SU1368269A1 - Device for pupifying waste water - Google Patents

Abstract

This invention relates to the biological treatment of domestic and industrial wastewater with activated sludge. The purpose of the invention is to increase the efficiency of the use of oxygen: and control the concentration of active sludge. This goal is achieved by equipping the device with primary and secondary continuous recirculation chambers 15 and 16, equipped with primary and secondary countercurrent chambers 19 and 20 of similar design, attached to fine-bubble dispersers 21 of both constant and periodic action, with a packed compactor 25 with a suspended sediment layer , located between the reactivator 12 and the reverse mixing corridor 7, with the separation of the deaeration 27 sludge mixture and prefabricated longitudinal trays 40. It is advisable that troystvo furthermore been provided with a supply of conductive grooves tangentially introduced into the expandable downward settling columns with internal screw lamelle nozzles and orifices in the laminating prefabricated trays iloulovi- ilouplotnitel bodies 8 and 25 with suspended sediment layer; direct recirculation and countercurrent chambers 15, 16 and 19, 20 were made of variable section; fine bubble dispersers of countercurrent chambers were connected to a source of technical oxygen or air enriched with technical oxygen, and at the end of the reverse mixing corridor of the aerotank there was made a separation of pre-oxygen-free gas with & 00 th

Description

S5 25 ZS Fig..Z

vanilla medium with a tray of incoming wastewater. Wastewater enters the corridor. 7 and by means of ka, measures 15 and 19 are sent as a mixture of activated sludge and water to corridor 6, from where they return to corridor 7 through chambers 16 and 20, depending on the load, the device can operate in different modes. The device allows to intensify the cleaning process and reduce operating costs. 5 hp f-ly, 7 ill.

one

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

The purpose of the invention is to increase the efficiency of oxygen utilization by adjusting the concentration of activated sludge.

FIG. 1 shows the device plan; in fig. 2, section A-A in FIG. one; in fig. 3 shows a section BB in FIG. one; in fig. 4 — device modification, plan; in fig. 5 shows a section B-B in FIG. four; in fig. 6 - section G-Y in FIG. 4; FIG. 7 is a section d-d in fig. four.

The device contains a rectangular case 1 of the aerotank, divided by longitudinal partitions 2 and 3 and transverse partitions 4 and 5 on the forward and backward mixing corridors 6 and 7, catcher 8 with conical attachments 9 and airlifts 10 attached to the slot-off tray 11, reactivator 12, fine bubble dispersers 13 connected to constant air blowers 14. .

The device includes main and additional recirculation chambers 15 and 16 with the main and additional counter chambers 19 and 20 that communicate with them through weirs 17 and 18. The recirculation cameras 15 and 16 are equipped with fine bubble dispersers 21 connected to air blowers 22 and 23 batch operation.

The devices are equipped with an adjustable threshold 24 located in: the starting area of the discharge tray, the silt sealer 25 with a suspended sediment layer formed by a transverse partition not reaching the bottom of the aerotank case and inclined at an angle of at least 45 to the bottom of the aerotank case partition wall 26, the upper edge of which is located above the liquid level in the back mixing corridor, by separating 27 the deaeration of the sludge mixture separated in the sludge compactor by means of a partition 28 which does not reach the bottom of the aerotank body, and submersible partition 29. The device also includes gutters 30–32 supplied to the cultivator, tangentially attached to the upper part of the precipitation columns 33-35 with internal screw thin-layer nozzles 36-38, prefabricated trays 39 and 40 of the catcher and the floatplot with a suspended sediment layer, equipped accordingly longitudinal

and cross-laminating nozzle25

mi 41 and 42.

The main and additional direct-flow recirculation and countercurrent chambers 15, 16, and T9, 20, respectively, have variable sections with expanding upper and lower parts 43 and 44, connected by middle sections 45 of the critical section, and fine-bubble dispergators 46, main and Additional counter-current chambers 19 and 2X) are connected to source 47 of technical oxygen or air enriched with technical oxygen. In addition, the device contains a compartment 48 of preliminary sedimentation of sludge medium, formed at the end of the back mixing corridor that does not reach the bottom of the aeration body

 cross partition 49, with tray

50 incoming wastewater inlet

51 and the release of the original and biologically purified waste liquid, the drain of 53 clarified waste liquid, the outlet 45 silt hole 54 and the bottom

slit 55, return activated sludge inlet 56, secondary clarifier 57, pumping device 58, air ducts 59 and oxygen-containing gas pipelines 60.

The device works as follows.

The waste water through the inlet 51 of the original waste liquid enters the reverse mixing corridor 7 of the aerotank and through the main recirculation chamber

15 through the spillway 17 and then through the main counter-flow chamber 19 are sent to the direct mixing corridor 6. The mixture of waste water and activated sludge reaches the end of the direct mixing corridor 6, where it is captured by an additional direct-flow recirculation chamber

16 and through the spillway 18 and the additional counterflow chamber 20 returns to the beginning of the reverse mixing corridor 7. The airlift effect of the main and additional flow recirculation chambers 15 and 16 created by the operation of the fine bubble dispersers 21 chambers is complemented by the oxidation effect created by the operation of the main and additional countercurrent chambers 19 and 20 together with fine bubble dispersers

13 other device compartments attached to the air blower

14 constant action.

In the process of recirculation of the sludge mixture through mixing corridors 7 and 6 and its continuous aztation, the process of biological purification or oxidation of organic pollutants of wastewater is carried out, and the ratio of the amount of recirculated sludge mixture to the amount of incoming wastewater is within 1, 5-3.

The mixture of activated sludge and purified waste liquid by gravity, a submerged partition wall 29 and a submerged transverse partition 5, is fed to a catcher 8, where the main (returnable) part of activated sludge is deposited in conical pits 9, and the primary clarification of the waste liquid enters the secondary clarifier 57 in which its final clarification and removal outside the system, with the active sludge deposited in the secondary clarifier from

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is transferred as surplus from the system for treatment or, if necessary, partially or fully returned to the reactivator 12 by any kind of pumping device 58.

The activated sludge deposited in conical pits 9 of the catcher 8, through airlifts 10, is sent to the desalting tray 11, from where through the sludge outlet 54 enters the reactivator 12. The activated sludge is adsorbed on the surface of the flakes 12 A regeneration cycle takes place, during which the adsorbed contaminants are processed by microorganisms, and the initial activity of the sludge is restored. The returning active sludge from the reactivator 12 is poured into the back mixing corridor 7 through the sludge compactor 25 with a suspended sediment layer so that the sludge mixture through the bottom slit 55 enters the flow part of the sludge compactor 25, and Branch 27 deaeration sludge mixture. In the process of lifting the sludge mixture to the longitudinal collection trays 40 and as a result of its movement through the suspended sediment layer, the concentration of return sludge entering the collection trays 40 and further into the back mixing corridor 7 decreases. On the one hand, this technological method allows maintaining —in the reactivator 12, elevated (on the order of 8–12 g / l) concentrations of activated sludge, which predetermines a reduction in its working volume, and on the other hand, maintains relatively low aerotank mixing corridors (1-2 g / l) the end Activation of activated sludge, sufficient for successful operation of the facility during the period of reduced technological loads on the aeration tank.

During the period of increased inflow of sewage and a corresponding increase in the technological load of organic pollutants on the structure, a periodical air blower 22 is turned on, as a result of which an increase in the amount of air introduced into the fine bubble bubble occurs.

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13 and 21. At the same time, an increase in the oxidation rates of contaminants associated with the dissolution and oxygen consumption rates, and the resulting tendency to disturb the homogeneous conditions of microorganism functioning, is compensated by a corresponding increase in the recirculation flow of the sludge mixture from the direct mixing plant. corridor 6 to the reverse mixing corridor 7, and vice versa. The ratio of the amount of recirculating sludge mixture to the amount of incoming wastewater is in the range of 3-6. At the same time, due to the rise of the level of the sludge mixture in the main and additional direct recirculation chambers 15 and 16, the sludge mixture through the adjustable threshold 24 enters the discharge tray 11 and from there through the outlet mud sludge 54 to the reactivator 12. In this case, the total consumption liquid entering the reactivator 12 and, consequently, into the seed compactor 25 with a suspended sediment layer

melts several times, as a result of which the process of sludge separation in the suspended sediment layer is replaced by the process of its accelerated displacement from the reactivator 12 into the reverse mixing corridor 7, as a result of which the working concentration of activated sludge in the mixture of gel corridors 6 and 7 begins to gradually increase, for example 2 to 3-4 g / l. This ensures the maintenance of the ratio of activated sludge - organic pollution - dissolved oxygen at a constant level with an increase in the technological load of more than 2 times.

If, in spite of these technological methods, as a result of a further increase in wastewater inflow, the increased oxidative requirements of the process are not met (which can be determined by measuring instruments, for example, a sensor of dissolved oxygen concentration installed at critical points of the device) 23 periodic action, similar to the blower 22 periodic action, with the only difference that the intensity of the control effect on the process is

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This is increasing, and the ratio of the amount of sludge mixture to the amount of incoming sewage is in the range of 6-10,

It is advisable that the catcher 8 be equipped with feed chutes 30-32, tangentially inserted into the downwardly expanding settling columns 33 - 35 with internal screw q-s thin-layer nozzles 36 - 38, and in prefabricated trays 39 and 40, the catcher 8 and the sealant 25 With the suspended sediment layer, longitudinal and transverse laminating nozzles 41 and 42 are installed respectively, respectively. Then the mixture of activated sludge and purified waste liquid through the feed troughs 30 - 32, tangentially inserted into the precipitation columns 33 - 35, enters the precipitation columns In the process of thin-layer screw movement of the sludge mixture from top to bottom, active sludge settles on the surface of the screw thin-layer nozzles 36 - 38 and slowly slides over them into conical attachments 9 of the catcher 8, and the clarified liquid exits through the bottom of the settling columns, passes through the longitudinal laminating nozzles 41, and enters the collector tray 39 of the catcher and then beyond the construction limits. This reduces the hydraulic load on the cross section of the flow section of the catcher 8 by reducing transit of the clarified water consumption, to ensure the most complete retention of both large and small fractions of flakes of active sludge, which makes the catcher 8 practically independent of the amount of wastewater inflow and minimizes the size of the secondary clarifier 57 and c. individual cases completely reject him. The transverse laminating nozzles 42 mounted in collecting trays 40 of the sludge compactor 25 with suspended sediment eliminate the possibility of the formation of transverse currents of sludge medium reducing the effect of clarification in the suspended layer, with the result that the concentration of activated sludge in the reactant 12 increases, for example, to 12-15 g / l

It is advisable that primary and secondary recirculation chambers 15 and 16 and

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The chamber chambers 19 and 20 were made of a tree section with expanding upper portions 43 and lower portions 44 connected by middle portions 45 of a critical section. In this case, the amplitude of oscillations of the operating level of the mixture in the recirculation recirculation chambers 15 and 16 increases, which consequently increases the control action of the additional recirculation recirculation chamber 16, in addition, the hydraulically favorable outlines of the cross section of the recirculation chambers increase their airlift effect, and the expanding lower parts of the countercurrent chambers 19 and 20 allow more complete dissolution of oxygen from bubbles of various diameters. Thus, larger bubbles will soar in the region of the critical section, the transition as the diameters decrease, due to fragmentation or loss of oxygen, to the expanding lower part.

It is desirable that the fine bubble dispersers 46 of the primary and secondary countercurrent chambers 19 and 20 are connected to the source 47 of technical oxygen or air enriched with technical oxygen. This technological procedure, in addition to increasing the amount of soluble

the oxygen of the silt medium and the possible oxidation of contaminants, while aeration of a constant action is calculated on the minimum load, and aeration of a periodic action on the maximum, which significantly reduces

Due to this purification of highly concentrated wastewater, it reduces the resistance of the main and additional countercurrent chambers 19 and 20 to the air-lift effect of the main and additional flow recirculation chambers 15 and 16, since the flow rate of technical oxygen through fine bubble dispersers 46 is at least 3-5 times less air flow when achieving a similar oxidative effect. In addition, the constant or periodic use of technical oxygen in the device reduces the increase in active sludge and improves its sedimentation properties.

It is desirable that the device be equipped with a section 48 of the preliminary de-oxygenation of the sludge medium gg with thin-layer spiral screws layered at the end of the reverse mixing corridor 7 by a transverse partition 49 not reaching the bottom of the aerotank body 49, with trays 50 arriving inlets, longitudinal and transverse laminating nozzles in prefabricated trays and flow patterns and white lines and transverse laminating nozzles in prefabricated trays and flow patterns and white lines and transverse laminating laminate patterns in prefabricated trays and white and translucent layers, and longitudinal and transverse laminating laminate nozzles, and longitudinal and transverse laminating nozzles in prefabricated trays and white and white translucent layers and in the longitudinal and transverse laminating laminate nozzles, and longitudinal and transverse laminating nozzles in prefabricated trays and flow patterns and flow patterns and longitudinal and transverse laminating nozzles in prefabricated trays and white and transverse laminating layers, and longitudinal and transverse laminating laminating nozzles in prefabricated trays and white and translucent lamellar flow patterns and longitudinal and transverse laminating laminate nozzles in prefabricated trays 49 , separation of pre-oxygen-free wastewater. This provides a preliminary short-term decrease in the concentration of dissolved oxygen in the sludge mixture, which allows more complete use of air oxygen or technical oxygen.

Thus, at the origin

Liquids through the construction of the process of dissolving oxygen are intensified due to the high rates of its consumption. Active microorganisms contained in the recirculating sludge medium receive an additional load as part of the incoming wastewater, thus stimulating the process of oxygen dissolution. During the period of increased loads on the structure

The oxygen consumption rate is significantly higher than the average for the facility, which allows for peak loads to be removed, ensures stable operation and reduces the total aeration time of wastewater. As a result of the operation of a controlled system of gas, and therefore of direct flow recirculation and countercurrent chambers, the load on the sludge is equalized along the length of the aerotank. Moreover, the amount of the recirculating sludge mixture varies depending on the load on the sludge, the possibility of controlling the biochemical process

Qi of constant action is calculated on the minimum load, and periodic aeration on the maximum, which significantly reduces

40 operating costs for electricity.

The design of the proposed device involves the use of new technological elements, such as the main and additional direct recirculation / chambers, the main and additional counterflow chambers equipped with fine-bubble dispersers attached to the air-guns of constant and periodic action, a compactor with a weighted sediment and separation of sludge de-aeration, precipitation columns with inlets, longitudinal and transverse laminating nozzles in prefabricated trays loulovitel and ilouplotnitel, separation prior obeskisloro

living silt medium, fine-bubble dispersers of countercurrent kama attached to a source of technical oxygen or air enriched with technical oxygen.

Claims (6)

1. Waste treatment device water, containing a rectangular aerotank case, divided by longitudinal and transverse partitions for direct and reverse mixing corridors and a catcher with modular trays and airlifts attached to the iloteck tray, a reactivator, a continuous recirculation flow chamber located at the end of the reverse mixing corridor, and fine bubble bottom pergators combined with constant and variable air blowers, characterized in that, in order to increase the efficiency of oxygen use by The concentration of activated sludge is equipped with an additional direct flow recirculation chamber located at the end of the direct mixing corridor, the main and additional countercurrent at the beginning of the direct and reverse mixing corridors are chambers with finely bubble dispersers of periodic action, while in the longitudinal partition there are weirs flow and countercurrent chambers, the drainage tray is supplied; an adjustable threshold and attached to an additional recirculation stream to As the device is also provided with income not conductive to the bottom housing aeroten 0 five Q five 0 five 0 as a transverse partition and inclined at an angle to the bottom of the body of the aerotank with a partition to form a sludge compactor and to separate the sludge deaeration, while the sludge compactor is provided with longitudinal collecting trays. 2. The device according to claim 1, that is, that the cinder is equipped with settling columns with internal thin-screw helical nozzles. 3. The device according to p. 1, about tl i amch. the fact that the catcher is provided with supply channels, tangentially attached to the upper part of the settling columns, and the collecting trays of the catcher and silt compactor are equipped with laminating nozzles. 4. The device according to claim 1, characterized in that the main and additional — direct winding and countercurrent chambers are made of variable cross section with widened upper and lower parts connected by middle parts of the critical section. 5. The device according to claim 1, about tl and often because the small-scale dispersers, the main and additional counter-current chambers are connected to a source of technical oxygen or air enriched with technical oxygen. 6. The device according to claim 1, wherein it is provided with a transverse partition not reaching the bottom of the body of the aerotank body to form a separation of pre-oxygenation of the sludge medium located at the end of the reverse mixing corridor. I'm 39/5 55 one Rygl //////////////////// у of FIG. five gd fffffff0mf f f /// f 55 of FIG. 6 dd 53. 55 .. 59