RU2064896C1 - Method and apparatus of physico-biological purification of sewage - Google Patents

Abstract

FIELD: urban and rural sewages purification. SUBSTANCE: method provides for aeration, first aeration and biochemical oxidation in aerotank, second aeration, separation of excessive active sludge, mixing of regenerated active sludge with operating active sludge and unpurified sewages. In the case after settling additional aeration is exercised, operating active sludge in mixture is fed by its returning from stream after additional aeration before first aeration and biochemical oxidation in aerotank. Total concentration of active sludge in mixing volume is kept in limits of 16 - 40 g/l. Apparatus has connected to each other by pipelines settler, flotators of first and second stages with slime pockets and discharge mechanisms, aerotank, locking capacities with pumps and ejectors mounted before each flotator and inlet and outlet pipelines. Settler has vertical partition, that divides it for chamber of mixing and chamber of settling. Aerotank is mounted between flotators. Slime pockets of flotators have pipelines connecting them with chamber of mixing. Ejectors chambers of mixing are communicated with atmosphere. EFFECT: increased effectiveness of purification per unit of volume of sewage purification plants 8 cl, 3 dwg, 1 tbl

Description

 The invention relates to the treatment of urban wastewater, agricultural complexes, wastewater containing organic pollution, including fats, petroleum products, surfactants.

 A known method of biochemical wastewater treatment, including sedimentation of wastewater, first aeration of wastewater and biochemical oxidation in aeration tank, separation of excess activated sludge and its regeneration, second aeration of wastewater, return of regenerated sludge to the beginning of the processing chain and mixing it with untreated wastewater and working activated sludge in aeration tank at a dose of activated sludge in the aeration tank in the range of 1-6 g / l. (1).

This method is characterized by the need to use elements of wastewater treatment plants of large volumes (total volume in the range of 25,000-40000 m ³ ) with a quantity of effluents of the order of 100,000 m ³ / day, which accordingly increases production areas and, consequently, increases capital and operating costs. Thus, in bringing to a unit of working volume of treatment facilities, this method is also characterized by low efficiency.

 A known installation of wastewater treatment, including interconnected pipelines of the first sump, flotators of the first and second stages, a closed vertical aeration tank, a second sump, pressure tanks with pumps and ejectors installed in front of each flotator, as well as inlet and outlet pipelines, and the outlet pipe connected to the second sump, the aeration tank is installed after the second-stage flotator, and the ejector mixing chambers communicate with the main aeration tank cap (2).

 The presence of biological treatment means in the line increases its efficiency, however, to ensure high efficiency of BOD cleaning, such a line requires a large volume aeration tank, which leads to the use of large production facilities and, accordingly, high capital and operating costs.

 The use of biogas (carbon dioxide) generated in the aeration tank leads to the complexity of the installation due to additional pipelines and means of sealing the aeration tank.

 Piping of activated sludge from the second sump to the inlet of the second flotation stage is not effective due to the practical absence of dissolved oxygen in the liquid being cleaned.

 The task to which the claimed invention is directed is to increase the efficiency of the method of physico-biological wastewater treatment and installation for its implementation per unit volume of treatment facilities and, thus, achieving the possibility of reducing the working volume and production space of treatment facilities with a corresponding reduction in capital and operating costs while ensuring a given degree of wastewater treatment.

 In FIG. 1 is a schematic representation of a physico-biological wastewater treatment plant.

In FIG. 2 shows the dependence of the total volume V of treatment facilities on the concentration a _{1 of} working sludge in the volume of the aeration tank for the known method and on the concentration of a ₂ sludges in the volume of the sump at a fixed concentration of working sludge in the aeration tank for the claimed method.

 In FIG. 3 shows the average dependence of the total volume V of treatment facilities on dose A of regenerated sludge with respect to the total dose of sludge in the sump for the claimed method.

 The physico-biological treatment plant includes a settling tank 1, separated by a partition 2 into a mixing chamber 3 and a settling chamber 4 and equipped with an inlet pipe 5 for supplying initial wastewater to the mixing chamber 3 of a settling tank 1 and a pipe 6 for withdrawing sludge for further processing, a pipeline 7 connecting sedimentation chamber 4 of the settler 1 with the first feed pump 8, supplying water to the first pressure tank 9, and with the first ejector 10 installed on the bypass pipe, as well as the first additional ejector 11, installed at the input of the flotator 12 of the first stage. The mixing chambers of the ejectors 10 and 11 communicate directly with the atmosphere. The first pressure tank 9 is provided with a pipe 13 to discharge excess air.

 The flotator 12 consists of a flotation chamber 14, a separation chamber 15, a slurry pocket 16, a drain device 17 with an adjustable overflow baffle 18 and includes a sludge removal mechanism 19. A pipe / or tray-20 is connected to the slurry pocket 16 of the flotator 12, connecting it to the sludge collector 21, to which, in turn, a pipe 22 is connected connecting the sludge collector 21 to the mixing chamber 3 of the settler 1 and having a branch 23 for outputting the sludge for further processing.

 The drain device 17 of the flotator 12 is connected by a pipe 24 to an open type aeration tank 25 equipped with bio-carriers 26, overflow devices 27 and a mechanism for collecting swollen sludge 28.

 The installation also includes a second stage flotator 29, consisting of flotation chambers 30 and separation chamber 31, a slurry pocket 32, a drain device 33 with an adjustable drain wall 34 and equipped with a sludge removal mechanism 35. Like the flotator 12 of the first stage, a second one is also installed in front of the flotator 29 of the second stage a pump 36, a second ejector 37, a second pressure tank 38 provided with a pipe 39 for discharging excess air, as well as a second additional ejector 40. The mixing chambers of the ejectors 37 and 40 communicate directly with a mosferoy. An additional pipeline 41 is connected to the pressure line section of the second pump 36 in front of the second pressure tank 38, connecting it to the aeration tank 25. A pipeline (or tray) 42 is connected to the slurry pocket Yu32 of the flotator 29, connecting it to the mixing chamber 3 of the settling tank 1. To the drain device 33 flotator 29 is connected to the output pipe 43.

 Installation works as follows.

 Wastewater containing pollutants through pipeline 5 enters the mixing chamber 3 of the settling tank 1, where it is mixed with reclaimed sludge coming in through the pipeline 42, and with working sludge coming in through the pipe 22. Next, the mixture enters the settling chamber 2 of the settling tank 1, where sedimentation of large suspensions. The sediment from the bottom of the sump 1 through the pipeline 6 is sent for further processing.

 By pump 8, the purified water is taken from the settling chamber 4 of the sump 1 and fed to the pressure tank 9. An ejector 10 is installed in the bypass line of the pump 8, through which the atmospheric air is sucked into the liquid stream. In the pressure tank 9, dissolution occurs under pressure of atmospheric air in the liquid to be cleaned. Excess air is vented through line 13. The saturation limit of the liquid with air is monitored visually by discharge from the line 13.

 The cleaned liquid after the pressure tank 9 is throttled in the ejector 11 and then fed into the flotation chamber 14 of the flotator 12 of the first stage. In the process of throttling, the pressure in the liquid decreases to almost atmospheric, which is accompanied by air desorption and intensive flotation in the chamber 14. The flotation sludge is separated from the liquid in the separation chamber 15 and collected on the liquid surface in the separation chamber 15 and collected on the liquid surface in the flotator 12. In the volume of the flotator 12 due to the saturation of water with atmospheric oxygen, an intensive process of chemical oxidation of dissolved organic substances occurs, which leads to a decrease in COD and MIC even without microorganisms.

 The clarified water through an adjustable overflow baffle 18 of the drainage device 17 enters the aeration tank 25 through a pipe 24. The adjustable baffle 18 allows to minimize the water saturation of the sludge.

 In the aeration tank 25, equipped with fixed or freely floating bio-carriers 26, there is an increase in the volume of biomass, which helps to increase its efficiency and productivity.

 The bio-treated water in the aeration tank 25, with excess activated sludge, enters the overflow device 27, from where the pump 36 is taken to the second flotation stage by a flotator 29, which works similarly to the flotator 12. From the drain device 33 of the flotator 29, the purified water passes through the pipe 43 from the treatment line.

 The pipeline 41 connecting the pressure line of the pump 36 to the aeration tank 25 allows for the recirculation of water with excess activated sludge to the aeration tank 25 and to produce additional aeration and mixing of the volume of the aeration tank 25.

 The flotation sludge formed in the flotator 12 of the first stage and consisting of pollutants and activated sludge is discharged by the sludge removal mechanism 19 into the sludge pocket 16 and through the pipeline (or tray) 20 enters the sludge collector 21, from where it is partially discharged through the pipeline 23 for further processing and partially through the pipe 22 is sent to the mixing chamber 3 of the sump 1.

 The flotation sludge formed in the flotator 29 of the second stage and consisting of the regenerated excess activated sludge is discharged by the sludge removal mechanism 25 into the sludge pocket 32, from where it is fed through the pipe (or tray) 42 to the mixing chamber 3 of the settling tank 1, where the newly active wastewater, active, is mixed sludge from the flotator 12 of the first stage, and regenerated excess activated sludge from the flotator 29 of the second stage. After mixing, the mixture through the settling chamber 4 of the sump 1 is again fed through the pipeline 7, thus starting a full cleaning cycle.

 Flotation reagents and solutions feeding microorganisms can also be introduced into the line through ejectors 10 and 37.

 The constructive implementation of the physico-biological wastewater treatment plant organizes its operation in a multi-stage biochemical treatment mode by ensuring the technical feasibility of the interaction of working activated sludge and regenerated activated sludge, respectively, received after flotation of the first stage and flotation of the second stage, at the very beginning of the working cycle and maintaining their biochemical activity in all elements of the line, while the whole process is carried out using atmospheric oxygen as bringing gas.

 The method of physico-biological wastewater treatment is as follows.

 In the initial, unfilled state of the treatment plant due to the exclusion of the aeration tank, where activated sludge has already been accumulated, the wastewater arriving for treatment in the sump 1 is subjected to a settling operation, during which heavy suspended particles fall out of it under the influence of gravity. Then, in the pressure tank 9, the effluents pass the first aeration under a pressure of 0.3-0.5 MPa and are saturated with oxygen. When leaving the pressure tank 9, the effluent is throttled almost to atmospheric pressure. After that, the flotation of the first stage is carried out, in which there is a removal with air bubbles into the foam layer, finer contaminating suspensions and the first chemical oxidation of the dissolved organics by oxygen in the liquid. The sludge is partially removed from the process for further processing, and partially returned to the sump. The clarified effluents are exposed to microorganisms, which, in a free-floating and attached state, are in aeration tank 25 in the form of active activated sludge at a concentration of 6-10 g / l. The concentration of dissolved oxygen in the aeration tank is maintained within the range of 3-8 mg / L. As a result of this, intense biochemical oxidation of pollutants occurs. After biochemical oxidation of pollutants. After biochemical oxidation in the aeration tank, the oxygen content in the treated effluents is below 2-3 mg / l. Therefore, in a further stream, the effluents are aerated a second time under a pressure of 0.3-0.5 MPa and saturated with atmospheric oxygen, and then throttled to atmospheric pressure. Next, the treated effluent, in which excess activated sludge is present, is subjected to flotation of the second stage, during which the excess activated sludge is regenerated and separated in the form of a slurry from the treated effluents. The sludge with regenerated activated sludge is returned to the beginning of the technological chain, to the sump. In the sump, the regenerated activated sludge is mixed with fresh sewage and it begins to actively oxidize pollutants, i.e., it passes into the state of working sludge. From the sludge tank, working sludge, mixed with effluents, enters the flotator 12 of the first stage, where in addition to the separation of suspended particles and chemical oxidation of dissolved organics, biochemical oxidation of pollutants and separation of working sludge from the liquid occur. The flotation sludge, consisting of pollutants and working activated sludge, is partially withdrawn for further processing, and partly fed to a sump.

 From this moment on, the process of physico-biological wastewater treatment is fully operational.

 In the sump, contact is made of working sludge after the first stage of flotation and regenerated sludge after the second stage of flotation. Since the electrochemical potentials of flakes of regenerated sludge returned after flotation of the second stage and flakes of working sludge returned after flotation of the first stage have, although insignificant, but different polarity electrochemical potentials, as a result of this contact, activated sludge is activated, which at a total concentration activated sludge in the mixing volume in the range of 16-40 g / l and the dose of regenerated sludge in the total content of activated sludge in the range of 10-90% and especially in the range of 30-40% prote repent most intensely. Due to this phenomenon, it becomes possible to carry out wastewater treatment processes for a given degree of purification in smaller wastewater treatment plants with a corresponding reduction in production areas and, consequently, capital and operating costs.

To determine the effectiveness of the proposed method was carried out a series of experimental cycles of wastewater treatment of urban type (household) in comparison with the known method. Tests were conducted on the claimed wastewater treatment plant. The comparison was carried out according to the total volume of treatment facilities with an equal degree of treatment. The test results are summarized in table. Example 1 presents data from the known method, example 2 shows the calculated data by the known method when changing the dose of working sludge in the aeration tank (a ₁ ) with fixed volumes of auxiliary elements of treatment facilities, in example 3 the calculated data by the known method with increasing volume of sludge separators for liquidation of the removal of sludge from wastewater treatment plants, in example 4, the calculated data according to the known method obtained by dividing the volume of the aeration tank into four consecutive sections using transverse partitions. In the remaining examples (5-10), the results of the experimental cycles according to the claimed method in the claimed wastewater treatment plant are presented.

The experiments according to the claimed method and the calculations for the known method were carried out with the following constant main technological parameters: the initial value of the military industrial complex ₅ = 400 mg / l, the volume of treatment plant elements without the aerotank volume of 4000 m ³ (for the claimed method), 9500 m ³ (for the known method without aeration tank and regenerator), the temperature of wastewater 15 ^o C, the average concentration of dissolved oxygen in the volume of the aeration tank 5 mg / L.

Variable parameters were:
and ₁ dose of working sludge in the volume of the aeration tank,
and _{2 (} total dose of regenerated and working sludge in the volume of the sump;
And the dose of regenerated sludge in the sump in relation to the total dose of sludge.

 During the experiments according to the claimed method to ensure a given degree of purification by BOD5, the working volume of the aeration tank was changed by installing a movable partition.

Based on the obtained calculated and experimental data, graphs are constructed of the dependence of the total volume of treatment facilities on the investigated parameters a ₂ (a ₁ ) and A.

In FIG. 2, curve 1 illustrates the calculated dependence for the known method (cf. example 2), curve 2 the calculated dependence for the known method, taking into account the need to increase the volume of sludge separators to eliminate sludge removal from treatment facilities (cf. example 3), curve 3 calculated dependence for the known method obtained under condition of separation of the aeration tank volume into four successive sections (cf. example 4.) and curve 4 - experimental dependence of the inventive method, when the average values of ₂ and 16 g / l and above, the parameter a (ca. ry 5-7). The graph also shows the geometric location (X-6 g / l, Y 39500 m ³ ) for the known method (example 3).

In FIG. 3 shows the experimental dependence of the total volume of treatment facilities on parameter A for the claimed method, averaged over parameter a ₂ in the range from 16 to 40 g / l (examples 8-10).

 Analysis of the data in the table and graphs shows that the use of the claimed method allows for an equal degree of treatment to reduce the total volume of treatment facilities on average 1.5-2.7 times compared with the known method, with a corresponding reduction in production space, as well as capital and operating costs. In this case, an excess of the total concentration of activated sludge in the mixing volume beyond 40 g / l leads to a significant removal of it into the treated effluents, i.e. to reduce the degree of purification, which entails the need to increase the volume of clarifiers to eliminate this phenomenon.

Claims (7)

 1. The method of physico-biological wastewater treatment, including the first aeration of wastewater with activated sludge and biochemical oxidation, the first sludge from biochemically treated water, the regeneration of activated sludge and mixing it with untreated sewage, the second aeration and the second sludge, characterized in that the second sludge is carried out before biochemical oxidation, return non-regenerated sludge is introduced into the mixture of untreated sewage and return regenerated sludge, additional aeration is carried out before the second sludge, and total concentration of activated sludge in the mixing volume is kept within 16 to 40 g / l. 2. The method according to p. 1, characterized in that the dose of regenerated sludge in the total content of activated sludge is maintained within 10 90%
3. Installation for physico-biological wastewater treatment, including interconnected sump pipelines, flotators of the first and second stages, containing slurry pockets and drain devices, aeration tank, pressure tanks with pumps and ejectors installed in front of each flotator, as well as inlet and outlet pipelines, characterized in that the sump is provided with a vertical partition separating it into the mixing chamber and the settling chamber, the aeration tank is installed between the flotators of the first and second stages, the sludge s flotators pockets of the first and second stages are provided with conduits connecting it with the mixing chamber of the settler, and the ejector mixing chamber communicated with the atmosphere.  4. Installation according to claim 3, characterized in that the aeration tank is equipped with bio-carriers.  5. Installation according to paragraphs. 3 and 4, characterized in that the outlet pipe is connected to the drain device of the flotator of the second stage.  6. Installation according to paragraphs. 3 5, characterized in that to the pressure line of the pump installed in front of the second stage flotator, an additional pipe is connected connecting it to the aeration tank.  7. Installation according to paragraphs. 3-6, characterized in that it is equipped with additional ejectors mounted on pipelines directly in front of the flotators of the first and second stages.  8. Installation according to paragraphs. 3 7, characterized in that the aeration tank is made in the form of an open type aeration tank.

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