RU2535842C1 - Installation for aerobic biological purification of sewage waters - Google Patents

Abstract

FIELD: chemistry.SUBSTANCE: installation contains a device for mechanical processing of initial sewage water for the separation of a solid sediment from it, a primary settler, an aerotank, a secondary settler, a device for the output of precipitated return and excess active sludge from the secondary settler, supply of return active sludge into the aerotank and discharge of purified water, two mixing devices, the first of which is successively connected to the device of mechanical processing of initial sewage water for the separation of the solid sediment from it and with a primary settler, the second is successively connected to the aerotank and the secondary settler. Also additionally to the lower edge of the secondary settler via the main pipeline connected is a device of physical-mechanical processing of the active sludge, representing the main pipeline with placed in it 4-6 perforated rigid membranes, located successively one after another along the length at different distances from each other, with an external diameter of the perforated rigid membranes coinciding with the internal diameter of the device of physical-mechanical processing of the active sludge, and the internal diameter of the perforated rigid membranes relates to the internal diameter of the device for physical-mechanical processing of the active sludge as (0.09-0.1):1. The device for physical-mechanical processing of the active sludge is successively connected to an accumulation tank, which is connected in parallel way via the main pipeline to the primary settler and to the secondary settler.EFFECT: increased efficiency of settling suspensions in the primary and secondary settlers, increased depth of biological purification in the aerotank, elimination of the necessity to output the excessive active sludge from the purification installations, its storage and utilisation.1 dwg

Description

The invention relates to biological wastewater treatment and can be used in wastewater treatment plants of settlements, agricultural and industrial enterprises.

The presence of a high level of wastewater contamination precludes the widespread use of traditional biological treatment plants, as for the full implementation of the removal of contaminants in the form of solid particles and dissolved nutrients, it is necessary to use modern technical equipment in combination with the latest scientific achievements in the field of biotechnology.

In most cases, aerobic biological treatment plants using activated sludge use a simple mechanical combination of physical processes for primary treatment and biological processes for the final treatment of wastewater. This technical solution proposes an installation that implements a combined technology for the treatment of wastewater by means of their physico-chemical and microbiological treatment.

The most relevant application of the invention for enterprises located directly within the city limits, when in addition to the requirements of a high degree of wastewater treatment, stringent requirements are placed on the discharge into the airspace of the exhaust gas during the treatment and the sanitary condition of the industrial sites of treatment facilities themselves. The use of the invention is also advisable in cases where the size of industrial sites is limited by adjacent residential areas, which does not allow the use of traditional aerobic biological treatment facilities that require large production areas.

A known installation for aerobic biological treatment (analogue), containing a primary sump, aeration tank with an aeration system for a mixture of wastewater and activated sludge, a secondary sump for separating waste water from activated sludge, a system for removing activated sludge from a secondary sludge, including means for returning activated sludge to aeration tank and withdrawal of excess activated sludge to sludge sites [1].

The disadvantages of this known installation are: low efficiency of biological treatment and the presence of significant quantities of excess activated sludge. This is due to the fact that the aerobic biological treatment section (aeration tank secondary sedimentation tank) operates under high loads of organic pollution, while the activated sludge biocenosis functions under non-optimal conditions of its life. As a result, the wastewater treatment indicators are not high enough and are far from the requirements that are imposed by the sanitary and epidemiological surveillance services on the waters discharged into the opening of water bodies and streams. In addition, the aeration tank directly takes on peak loads of organic pollutants, which are associated with a significant unevenness in the supply of initial effluents and are due to specific features of the production technological cycle of the enterprise.

In view of this, disruptions in the operation of treatment facilities are possible, manifested in the swelling of activated sludge in aeration tanks, inhibition of activated sludge microorganisms and the practical termination of its functioning in aeration tank during a biochemical process. In addition to the above, under these conditions, due to the release of significant amounts of excess activated sludge, sludge cards are overloaded and production difficulties associated with the disposal of activated sludge from treatment plants and subsequent waste disposal.

A known installation for the implementation of aerobic biological wastewater treatment (prototype), comprising a mechanical treatment device for the source wastewater for separating solid sludge from it, a primary sump, aeration tank, a secondary sump, a device for removing precipitated return and excess activated sludge from the secondary sludge, supplying return active sludge into the aeration tank and drainage of purified water [2].

A disadvantage of the known installation is the low cleaning efficiency, the need to remove excess activated sludge and its subsequent disposal. These shortcomings are due primarily to the fact that the degree of treatment substantially depends on the contamination of the source wastewater entering the treatment plant. Organic impurities in the initial wastewater are, as is known, in dissolved, colloidal and solid-phase (coarse and finely dispersed) states.

At the same time, the fine-dispersed substance of pollution is characterized by unsatisfactory sedimentation, which does not allow isolating it at the stage of mechanical treatment, in particular in primary settling tanks. As a result of this, an increase in the concentration of suspended solids in the initial wastewater enters the biological treatment site, which inevitably leads to a significant deterioration in the cleaning performance in aeration tanks. In addition, a feature of most production technological processes at enterprises is the presence of salvo changes in the composition of the initial wastewater supplied to the treatment plant during the day.

Sharp fluctuations in the concentrations of suspended solids in the initial wastewater entering the treatment plant have a particularly unfavorable effect on the biological treatment process due to disturbance in the diet of complex biocenoses of activated sludge from aeration tanks. The low quality of wastewater treatment is also associated with the relatively low efficiency of separating activated sludge from a mixture of it with wastewater at the outlet of aeration tanks in the secondary settling tanks. This is due to the fact that biofloculation of activated sludge in aerotanks and secondary sedimentation tanks is not intensive enough due to low concentrations of extracellular biopolymers in the sludge suspension. In addition, the technical biological treatment process in aeration tanks is accompanied by a significant increase in biomass, which leads to the presence of significant amounts of excess activated sludge at the outlet of the treatment plant. The removal of excess activated sludge from wastewater treatment plants to sludge sites and the need to build these sites for the storage and disposal of large masses of these wastes is a serious difficulty and requires significant energy and labor costs.

The objective of the invention is to increase the efficiency of wastewater treatment, reduce the yield of excess activated sludge from treatment plants and the need for its disposal, increase the reliability of treatment facilities.

The problem is solved in the installation for aerobic biological wastewater treatment, containing a device for the mechanical treatment of the source wastewater to separate the solid sludge from it, a primary sump, aeration tank, a secondary sump, a device for removing precipitated return and excess activated sludge from the secondary sludge, and supplying return activated sludge in aeration tank and drainage of purified water by the fact that it additionally contains two mixing devices, the first of which is connected in series with the device treatment of the source waste water to separate the solid sludge from it and with the primary sump, the second is connected in series with the aeration tank and the secondary sump, and in addition to the lower edge of the secondary sump, a device for physically-mechanical processing of activated sludge is connected, which is a main pipe with in it 4-6 perforated rigid membranes arranged sequentially one after another along the length at equal distances from each other, p When in use, the outer diameter of the perforated rigid membrane coincides with the inner diameter (d _1, m) of the device physico-mechanical treatment of the activated sludge, and the inner diameter of the perforated rigid membrane refers to the inner diameter of the device physico-mechanical processing as an active sludge (0,09-0,1 ): 1, also the device for physicomechanical processing of activated sludge is connected in series with the storage tank, which is parallelly connected through the main pipeline to the primary sump and to the secondary sump.

To obtain the maximum amount of exopolysaccharides, activated sludge is used, which is in the endogenous phase of metabolism in the process of aerobic biological wastewater treatment in aeration tank. The endogenous phase of metabolism is provided by creating regimes for the cultivation of microorganisms during aerobic biological treatment in an aeration tank, providing a consistent change in their nutritional conditions from excess nutrient substrate to deep aging microorganisms. The composition of the activated sludge biocenosis in the process of aerobic biological treatment is formed mainly from flocculating microorganisms by selection in the aerotank of a consortium of bacteria (Zoogloea ramigera, Sphaerotillus natans, Leprothrix ochracea, Acetobacter aceti, Sarcina ventriculi, Lampropedia hygiene). suppressing the growth of filamentous and non-flocculating microorganisms.

The device for physicomechanical processing of activated sludge consists of two parallel-connected units for processing activated sludge, which subsequently enters the primary and secondary sumps. The blocks of physical and mechanical processing of activated sludge are made in the form of containers equipped with mechanical mixing devices such as mixers or hydraulic mixing devices, for example, circulation pumps.

The blocks of physical and mechanical processing of activated sludge are made in the form of throttling devices, consisting of perforated rigid membranes located in the main material pipelines, arranged sequentially one after another along the length of the material pipeline at distances providing a consistent narrowing of the treated sludge suspension stream. The passage sections of the membranes decrease along the movement of the silt suspension.

These circumstances indicate that the claimed technical solution meets the criterion of "novelty."

Comparison of the claimed installation with the known shows that they for the specialist do not follow explicitly from the prior art, which indicates that the claimed technical solution meets the criterion of "inventive step".

The claimed technical solution is industrially applicable and is used at a number of existing treatment facilities for aerobic biological treatment of both industrial and domestic wastewater.

Figure 1 shows a diagram of the proposed installation for aerobic biological wastewater treatment.

An apparatus for aerobic biological wastewater treatment contains a mechanical treatment device (1) of the initial wastewater to separate solid sediment from it, a primary settler (2), an aeration tank (3), a secondary settler (4), and output devices (5) for deposited return and excess activated sludge from the secondary sump, a device (6) for returning activated sludge to the aeration tank (3) and a purified water drain (7), additionally contains two mixing devices (8 and 9), the first (8) of which are connected in series with the device mechanical processing (1) of the initial wastewater to separate the solid sludge from it and with the primary sump (2), the second (9) is connected in series with the aeration tank (3) and the secondary sump (4), also in addition to the lower edge of the secondary sump (4) ) through the main pipeline (10), a device for physicomechanical processing (11) of activated sludge is connected, which is a main pipeline with perforated rigid membranes placed in it (12), arranged consecutively one after the other along the equal lengths standing apart, the device for physicomechanical processing (11) of activated sludge is connected in series with the storage tank (13), which is connected in parallel through the main pipeline (14) with the primary settler (2) and through the main pipeline (15) with the secondary settler ( four). In addition, the installation for aerobic biological wastewater treatment contains the removal of excess activated sludge (16) from the technological scheme of treatment facilities for disposal.

Installation works as follows.

The feed wastewater enters the mechanical treatment device (1) of the feed wastewater to separate the solid sludge from it, where solid sludge is removed. After that, the wastewater is supplied to a mixing device (8), where it is mixed with previously treated excess activated sludge from a storage tank (13). In the process of mixing, flocculation of solid and colloidal particles of contaminants into large aggregates that are well deposited in the primary sedimentation tank (2). The slocculated suspension from the mixing device (8) enters the primary sump (2), where the crude sediment is separated from it.

The clarified wastewater, largely freed from dispersed organic pollutants, is discharged to the aerobic biological treatment section in the aeration tank (3), where it is biochemically treated in the presence of return activated sludge recycled from the secondary sump (4). A mixture of biologically treated wastewater and activated sludge discharged from the aeration tank (3) is fed into a mixing device (9), where it is mixed with previously treated activated sludge. Pretreatment of activated sludge entering the mixing device (9) is carried out in a physical-mechanical processing device (11).

When mixing a mixture of wastewater and activated sludge from an aeration tank with a pre-treated sludge suspension, flocculation of activated sludge bacteria into large cell aggregates is carried out, which are effectively deposited further in the secondary sump (4). After settling in the secondary sump (4), the purified and clarified wastewater is discharged from the secondary sump (4) through the output device (5) of the deposited return and excess activated sludge from the secondary sludge beyond the treatment facilities, and the sludge (activated sludge) is discharged from the secondary sump (4) and is divided into three parts: one part (return activated sludge) is returned to the aeration tank (3) through the feed device (6) of return activated sludge to participate in the biochemical purification process, the second part is subjected to physical and mechanical chemical processing through a device for physico-mechanical processing (11) of activated sludge and storage tank (13) to isolate bioflocculants and intensify the flocculation process, and the third part is disposed of through the excess activated sludge (16) from the technological scheme of treatment facilities.

As a result of physico-mechanical treatment of activated sludge in the sludge suspension, two effects take place:

- an increase in the concentration of biopolymers due to their isolation from cellular structures;

- degradation of flocs, as a result of which there is a transition of bioflocculants into suspension and an increase in the concentration of flocculation centers.

As a result of this, due to the increase in the content of dissolved biopolymers of the suspension after its physical and mechanical treatment, the biological oxygen demand (BOD) increases. When this suspension is mixed with wastewater, intense flocculation of suspensions in wastewater is observed and, as a result, their intensive sedimentation in the sump. Therefore, the concentration of suspended solids in clarified water at the outlet of the sump decreases. But at the same time, protein substances dissolved in the wastewater and not retained by the settler leave it with clarified water, i.e. the high content of BOD is maintained after the sump. However, protein substances dissolved in water are carbon compounds, which are easily assimilated nutrients for microorganisms. As a result, the nutritional balance of microorganisms shifts toward more easily assimilable “products”, which leads to a decrease in biologically oxidized contaminants at the exit of the aeration tank, i.e. to reduce BOD in purified water. As a result, the proposed device provides a decrease in both the concentration of suspended solids and nutrients in purified water, i.e. improvement of the whole complex of integrated characteristics of water discharged from treatment facilities.

The invention is illustrated by the following examples:

Example 1. Laboratory of the Department of Industrial Sanitation and Environmental Protection of the All-Russian Research and Technological Institute of Biological Industry.

The type of wastewater is domestic, wastewater from biological enterprises, livestock complexes (pig breeding, cattle, poultry), meat and dairy enterprises. The working volume of tanks (mixing, settling tanks) 40 liters. The feed wastewater enters the mechanical treatment device (1) of the feed wastewater to separate the solid sludge from it, where solid sludge is removed. After this, the wastewater is supplied to a mixing device (8), where it is mixed with previously treated excess activated sludge from a storage tank (13) through a main pipeline (14). In the process of mixing, flocculation of solid and colloidal particles of contaminants into large aggregates that are well deposited in the primary sedimentation tank (2). The slocculated suspension from the mixing device (8) enters the primary sump (2), where the crude sediment is separated from it.

The clarified wastewater, largely freed from dispersed organic pollutants, is discharged to the aerobic biological treatment section in the aeration tank (3), where it is biochemically treated in the presence of recirculated activated sludge recirculated from the secondary sump (4) through the recirculation device (6) activated sludge. A mixture of biologically treated wastewater and activated sludge discharged from the aeration tank (3) is fed into a mixing device (9), where it is mixed with pre-treated activated sludge coming from a storage tank (13) through a main pipeline (15). Pretreatment of activated sludge entering the mixing device (9) is carried out in a physical-mechanical processing device (11).

When mixing a mixture of wastewater and activated sludge from an aeration tank with a pre-treated sludge suspension, flocculation of activated sludge bacteria into large cell aggregates is carried out, which are effectively deposited further in the secondary sump (4). After settling in the secondary sump (4), the purified and clarified wastewater is discharged from the secondary sump (4) outside the sewage treatment plant through the output device (5) of the deposited return and excess activated sludge, and the sludge (activated sludge) is discharged from the secondary sump (4) and is divided into three parts: one part (return activated sludge) is returned to the aeration tank (3) through the feed device (6) of return activated sludge to participate in the biochemical purification process, the second part is subjected to physical and mechanical processing through a device for physicomechanical processing (11) of activated sludge and storage tank (13) to isolate bioflocculants and intensify the flocculation process, and the third part is disposed of through the excess activated sludge (16) from the technological scheme of treatment facilities. The physical-mechanical processing device (11) of activated sludge is a main pipeline with four perforated rigid membranes located in it (12), arranged sequentially one after another along the length at equal distances from each other, and the outer diameter of the perforated rigid membranes coincides with the inner diameter physical and mechanical processing devices (11) of activated sludge, and the inner diameter of perforated rigid membranes refers to the internal diameter of the physical and mechanical device Work (11) of activated sludge as 0.1: 1. Processing of activated sludge in a device for physicomechanical processing of activated sludge is a hydromechanical effect. Next, part of the treated activated sludge is mixed with the original wastewater before it is fed to the primary sump, and the other part is supplied with a mixture of wastewater and activated sludge discharged from the aeration tank before it is fed to the secondary sump. The settled layer from the secondary sump (4) is discharged from the installation for aerobic biological wastewater treatment through a drainage device (7) of purified water.

The efficiency of wastewater treatment according to the main integral indicators corresponded to: a concentration of suspended solids of 5 mg / l and a biochemical oxygen demand (BOD) of 6 mgO ₂ / l, i.e. cleaning efficiency improved by 60% compared with the known device.

Example 2. Laboratory of the department of industrial sanitation and environmental protection of the All-Russian Research and Technological Institute of Biological Industry

The type of wastewater is domestic, wastewater from biological enterprises, livestock complexes (pig breeding, cattle, poultry), meat and dairy enterprises. The working volume of tanks (mixing, settling tanks) 40 liters. The feed wastewater enters the mechanical treatment device (1) of the feed wastewater to separate the solid sludge from it, where solid sludge is removed. After this, the wastewater is supplied to a mixing device (8), where it is mixed with previously treated excess activated sludge from a storage tank (13) through a main pipeline (14). In the process of mixing, flocculation of solid and colloidal particles of contaminants into large aggregates that are well deposited in the primary sedimentation tank (2). The slocculated suspension from the mixing device (8) enters the primary sump (2), where the crude sediment is separated from it.

The clarified wastewater, largely freed from dispersed organic pollutants, is discharged to the aerobic biological treatment section in the aeration tank (3), where it is biochemically treated in the presence of recirculated activated sludge recirculated from the secondary sump (4) through the recirculation device (6) activated sludge. A mixture of biologically treated wastewater and activated sludge discharged from the aeration tank (3) is fed into a mixing device (9), where it is mixed with pre-treated activated sludge coming from a storage tank (13) through a main pipeline (15). Pretreatment of activated sludge entering the mixing device (9) is carried out in a physical-mechanical processing device (11).

When mixing a mixture of wastewater and activated sludge from an aeration tank with a pre-treated sludge suspension, flocculation of activated sludge bacteria into large cell aggregates is carried out, which are effectively deposited further in the secondary sump (4). After settling in the secondary sump (4), the purified and clarified wastewater is discharged from the secondary sump (4) outside the sewage treatment plant through the output device (5) of the deposited return and excess activated sludge, and the sludge (activated sludge) is discharged from the secondary sump (4) and is divided into three parts: one part (return activated sludge) is returned to the aeration tank (3) through the return device (6) of return activated sludge to participate in the biochemical treatment process, the second part is subjected to physical and mechanical treatment through device physico-mechanical processing (11) of the activated sludge and the collecting vessel (13) for isolating and intensification bioflokulyantov flocculation process, and the third part through the excess sludge removal (16) of the flowsheet of treatment facilities utilized. The device for physicomechanical processing (11) of activated sludge is a main pipeline with six perforated rigid membranes (12) located in it, arranged sequentially one after another along the length at equal distances from each other, and the outer diameter of the perforated rigid membranes coincides with the inner diameter physical-mechanical processing devices (11) of activated sludge, and the inner diameter of perforated rigid membranes refers to the internal diameter of the physical-mechanical processing device edema (11) of activated sludge as 0.09: 1. Processing of activated sludge in a device for physicomechanical processing of activated sludge is a hydromechanical effect. Next, part of the treated activated sludge is mixed with the original wastewater before it is fed to the primary sump, and the other part is supplied with a mixture of wastewater and activated sludge discharged from the aeration tank before it is fed to the secondary sump.

The settled layer from the secondary sump (4) is discharged from the installation for aerobic biological wastewater treatment through a drainage device (7) of purified water.

The efficiency of wastewater treatment according to the main integral indicators corresponded to: a concentration of suspended solids of 5 mg / l and a biochemical oxygen demand (BOD) of 6 mgO ₂ / l, i.e. cleaning efficiency improved by 60% compared with the known device.

Next, 80% of the treated activated sludge is mixed with the source wastewater before it is fed to the primary sump, and 20% is mixed with a mixture of wastewater and activated sludge discharged from the aeration tank, before it is fed to the secondary sump, while the processes of mixing these suspensions are carried out for 20 min with an intensity corresponding to the dimensionless Reynolds coefficient Re = 4000.

The efficiency of wastewater treatment according to the main integral indicators corresponded to: a concentration of suspended solids of 4 mg / l and a biochemical oxygen demand (BOD) of 5 mgO ₂ / l, i.e. the cleaning efficiency improved in comparison with the known method by 80%.

Thus, the claimed technical solution allows to increase the efficiency of sedimentation of suspensions in the primary and secondary sedimentation tanks, to increase the depth of biological treatment in the aeration tank, to eliminate the need to remove excess activated sludge from treatment facilities, its storage and disposal. Studies conducted to test the proposed technical solution showed that in comparison with the prototype, the efficiency of wastewater treatment is increased by 60-80%.

Literature:

1. Yakovlev S.V., Kareliy Y.A., Zhukov A.I., Kolobanov S.K. Sewerage. - M .: Stroyizdat, 1975, p. 390-392, Fig. 4.131 (analogue).

2. Yakovlev S.V., Kareliy Y.A., Zhukov A.I., Kolobanov S.K. Sewerage. - M .: Stroyizdat, 1975, p.208-215, Fig. 4.12v (prototype).

Claims (1)

Installation for aerobic biological wastewater treatment, containing a device for the mechanical treatment of source wastewater for separating solid sludge from it, a primary sump, an aeration tank, a secondary sump, a device for removing precipitated return and excess activated sludge from a secondary sludge, supplying return activated sludge to the aeration tank and discharge purified water, characterized in that it further comprises two mixing devices, the first of which is connected in series with the machining device source sewage to separate the solid sludge from it and with the primary sump, the second is connected in series with the aeration tank and the secondary sump, and in addition to the lower edge of the secondary sump, a device for physicomechanical processing of activated sludge is connected, which is a main pipe placed in it 4-6 perforated rigid membranes arranged sequentially one after another along the length at equal distances from each other, and the outer di meter perforated rigid membranes coincides with the inner diameter of the device for physico-mechanical processing of activated sludge, and the inner diameter of the perforated hard membranes refers to the inner diameter of the device for physico-mechanical processing of activated sludge as (0.09-0.1): 1, also a device of physical mechanical processing of activated sludge is connected in series with the storage tank, which is parallel connected through the main pipeline to the primary sump and to the secondary sump.

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