RU2252193C2 - Installation of sewage biological purification - Google Patents

Abstract

FIELD: sewage biological purification equipment.

SUBSTANCE: the invention is pertaining to installations of household and similar industrial sewage biological purification and may be used in a municipal economy and at industrial enterprises. Installation of sewage biological purification consists of: a tank divided by partitions into steps, sections, chambers of steps of bioreactors; systems for sewage feeding, distributing and withdrawing; a system of recirculation of sludge mixtures; a system of air supply; thin-layer pulsed silt master units, a filamentary nozzle for retaining of hydrocoles; communications for sewage settlings separation from the sewage biological purification installation. The tank is made three-staged with the different size steps. The second stage is twice as large as the first one, and the third stage by one third exceeds the first step. The first and the second steps are supplied with chambers of the thin-layer pulsed silt master units. The dimensions of a thin-layer pulsed silt master unit in the first step are in one and a half times less than the similar units in the second step. In essence the first step is made as an ideal mixer, and the second and the third steps - largely as displacers. The nozzle is located in the second and third steps. Communications for withdrawal of the sewage settlings beyond the limits of the installation are placed exclusively in the third step. The technical effect is an increase of efficiency of removal from the sewage of phosphorus and nitrogen, a multiple decrease of the specific volume of tanks, a decrease of power input and simplification of operation.

EFFECT: the invention ensures increased efficiency of removal from the sewage of phosphorus and nitrogen, a multiple decrease of the specific volume of tanks, decreased power input and simplification of operation.

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Description

The invention relates to devices for biological treatment of household and close to them in the composition of industrial wastewater and can be used in communication facilities and industrial enterprises.

Known devices for biological wastewater treatment [1], in which the wastewater freed from large mechanical impurities by thinning and settling in the sand traps is sent for treatment with free-floating activated sludge returned after subsequent sedimentation of the sludge mixture for reuse. Known devices guarantee biological removal with removable sediments of not more than 30% phosphorus, up to 70% nitrogen, require a tank capacity for wastewater treatment up to 1 m ³ / m ³ wastewater (relative to daily consumption) and at least 0.5 kWh electricity per 1 m ^{3 of} wastewater. Such parameters of the operation of the plants do not meet modern requirements both in terms of purification, and in terms of investment and operating costs.

The closest in technical essence to the device that is claimed is a plant for biochemical wastewater treatment [2], including a tank divided by vertical partitions into sections and compartments of a multi-stage bioreactor, communication systems for supplying, distributing and discharging wastewater, recirculation of silt mixtures, air supply, equipment for the separation of diluted sludge mixtures, a fibrous nozzle for holding immobilized hydrobionts, thin-layer pulsation sludge separators and devices accretion to them, providing pulsation of the water level.

The installation provides a slight decrease in the volume of the tank, but does not improve the efficiency of nitrogen and phosphorus removal, simplify operation and reduce specific energy consumption, significantly reduce the specific volume of facilities per unit volume of treated wastewater.

The basis of the invention is the task of improving the installation for biochemical wastewater treatment, in which a tank divided by partitions into steps, sections and compartments having thin-layer pulsation sludge separators, a fiber nozzle for holding hydrobionts, a communication system for supplying, distributing and discharging wastewater, sludge recycling mixtures, air supply and removal of accumulating excess sludge to thicken and subsequent dehydration, is performed in three stages with different levels , at the first and second stages with thin-layer pulsating sludge separators, in the first stage with an ideal mixer, in the second and third stages with displacers, with the removal of sludge exclusively from the third stage, which ensures an increase in the efficiency of removal of phosphorus and nitrogen from wastewater, a multiple decrease in the specific volume of containers installation, reducing energy consumption and simplifying operation.

The problem is solved in that the biological wastewater treatment plant in accordance with the invention includes a reservoir divided by partitions into steps and sections, and compartments of bioreactor steps, communication systems for supplying, distributing and discharging wastewater, recirculation of silt mixtures, air supply, thin-layer pulsation sludge separators, a fiber nozzle for holding hydrobionts, communications for removing sewage sludge from a treatment plant. The tank is made in three stages with different-sized steps, with the second stage being twice as large as the first, and the third stage being one third more than the first; the first and second stages are equipped with compartments of thin-layer pulsation sludge separators, while the dimensions of the thin-layer pulsation sludge separator in the first stage are one and a half times smaller than in the second stage; in shape, the first stage is made by an ideal mixer, and the second and third stages are largely displaced; the nozzle is placed in the second and third stages, and communications for removing sewage sludge outside the installation are provided exclusively in the third stage.

Patent studies have shown that neither the patent nor the scientific and technical literature contain information about the biological wastewater treatment plant in the manner described in the claims, which suggests that the proposed installation meets the criterion of “novelty”.

A comparative analysis of devices that are used in well-known technical solutions, including in the prototype, showed significant features that distinguish the proposed solution.

The advantages that are achieved indicate that the tasks that are being solved are performed at the inventive step, since it does not follow obviously from solutions known in the art and therefore meets the patentability criterion of “inventive step”.

The proposed installation is illustrated by drawings, where in Fig. 1 is a biological wastewater treatment plant, Fig. 2 is the dependence of the phosphorus content in the dry sludge matter on the daily load according to BOD in _full , Fig. 3 is the dependence of the removal of suspended solids from sludge flow rate in a thin layer pulsation sludge separator.

The biological wastewater treatment plant consists of a rectangular tank 1, a wastewater inlet tray 2 into the first 3 wastewater treatment stages, equipped with a compartment with a thin-layer pulsating sludge separator 4. In the first 3 stages of the bioreactors, bubblers 5 for aeration of the sludge mixture are placed on the bottom. From the pallet of the thin-layer pulsating sludge separator 4, sludge is discharged by airlift 6 to the place of wastewater inlet to stage 3. Partially purified sewage liquid from the sludge separator 4 through the tray 7 is discharged to the second 8 stage. The second stage 8 is a two-corridor aeration tank. There are bubblers 5 located on the bottom of the aeration tank. At the end of the second aeration tank corridor there is a thin-layer pulsating desilter 9 separating the sludge mixture of the aeration tank into two streams. One stream airlift 10 pumps the sludge mixture through the partition 11 to the entrance of the first aeration tank corridor to the place where the tray 7 supplies the waste fluid from the first 3 stages of bioreactors. The second stream along the tray 12 is discharged discharges waste fluid into the third 13th stage, divided by a partition 14 into two parallel working sections. The third stage 13 bioreactors and the second corridor of the second 8 stages are equipped with a fibrous nozzle 15 in the form of transverse curtains to the entire depth of the water in the tank.

A hydromechanized communication system 16 is mounted on the bottom of tank 1 in the third 13th stage of bioreactors to remove wastewater sludge from tank 1 for thickening and dehydration. On the bottom of the tank 1 in the third 13 steps, 5 aeration bubblers are laid.

Installation of biological wastewater treatment is as follows.

Wastewater flows through tray 2 into reservoir 1, into its first 1 stage, made by an ideal mixer. Located in the first 3 stages, a thin-layer pulsating sludge separator 4 separates suspended wastewater substances with a growing heterotrophic bacterial biocenosis from the wastewater and airlift 6 returns it continuously to mix with the flow of wastewater entering the tray 2. The air supplied through the aeration bubblers 5 constantly mixes the waste fluid and the sludge mixture from the airlift 6, while simultaneously introducing oxygen for the needs of the oxidation processes. Separated from the main mass of suspended solids in the sludge separator 4, the waste fluid flows through the tray 7 into the second 8 stage of the bioreactors. The second 8 stage is also equipped with aeration bubblers 5 and has a thin-layer pulsating sludge separator 9, which ensures the separation of waste fluid and free-floating activated sludge. At the same time, activated sludge with airlift 10 is fed through the longitudinal vertical partition 11 to the place where the wastewater is introduced into the second 8th stage by the tray 7, the mixture of activated sludge and wastewater is continuously aerated and moves due to the directional surfaces of the enclosing wall and the longitudinal vertical partition 11 to the entrance to the collecting tray sludge separator 9. Wastewater treated by activated sludge of the second stage 8 and attached to the nozzle 15 by a biocenosis through a tray 12 by gravity flows into the third 13 stage of bioreactors. The third 13th stage is divided by a vertical partition 14 into two parallel working sections and is equipped with transverse curtains made of fibrous nozzle 15. The hydrobionts living on the fibrous nozzle (filtrators and sedimentators) eat activated sludge carried out from the second 8th stage, delayed by the curtains of the fibrous nozzle 15 due to forces of electrostatic attraction, mineralize and in the form of feces and pseudofecals are thrown into the purified water. Due to the fact that there are non-aerated zones between the curtains, feces and pseudo-feces settle to the bottom. By alternately activating the hydromechanized communications system, 16 sludge from parallel sections is discharged outside the reservoir 1 for thickening and dehydration. The purified wastewater on the tray 17 is discharged for disinfection.

The ratio of the sizes of the three steps relative to each other is due to the following circumstances. It was experimentally established (Fig. 2) that with an increase in the daily load on the biocenosis of free-floating microorganisms by the amount of easily digestible organic substances, the enzyme system of heterotrophic bacteria changes in composition, the content of ATP (adenosine triphosphoric acid) increases and the protein substance of bacteria becomes more saturated with phosphorus. Already at a load of 1 kg BODP / kg of ash-free substance of microorganisms per day, the phosphorus content in the protein system of sludge increases to 30 mg of phosphorus per 1000 mg of dry sludge, while in sludges of traditional aeration tanks working with traditional loads of 0.2-0, 6 kg BOD _p / kg ash-free substance per day, the phosphorus content is in the range of 10-12 mg R / g dry matter.

In view of the above, it is necessary to ensure the residence time of wastewater and the biomass of heterotrophic sludge, corresponding to the load of organic substances on the biomass of sludge at the level of 1000 mg BOD _p / g ashless substance per day. The sludge biomass value in the stage is ensured by a thin-layer pulsating sludge separator and airlift productivity, pumping sludge from the sludge trap. Of course, the sedimentation properties of highly loaded heterotrophic sludge in the first stage are also important. The operating experience of experimental treatment plants showed that the sludge index of highly loaded heterotrophic sludge is in the range of 90-100 ml / g. Therefore, to maintain the sludge in the biomass stage at a concentration of about 3 kg / m ³ on dry matter, which corresponds to the ability of the aeration system to introduce oxygen to oxidative processes, given the higher oxidative power of 1 kg of ash-free sludge material per unit time, almost twice the oxidizing the sludge capacity of traditional aeration tanks operating with the above traditional loads, airlift recycling of at least 50-60% of the estimated wastewater flow rate will be required. If we take into account that about half of the dissolved organic impurities in domestic wastewater are easily oxidized and can be disposed of in the first stage at specific speeds twice as high as in the second stage, then with a volume of the second stage twice as large as the first stage, and with equal biomass concentrations hydrobionts in these stages, the load on the sludge of the second stage will be 4 times less than the sludge in the first stage, and it is necessary to have a load less than 5 times. To reduce the load, one should either increase the biomass of sludge in the second stage or increase the volume of the stage, which contradicts the task of the invention. An increase in sludge biomass in excess of 3 kg / m ^{3 is} also impractical, since the proportion of actively working microorganisms is sharply deteriorating. Hence, the difference in sludge load by 5 times should be made by reducing the biomass of bacteria in the first stage. In addition, the growth of sludge in the first stage depends entirely on the concentration of suspended solids in the effluent supplied to the treatment, since heterotrophic bacteria of fast-growing sludge grow exclusively on suspended solids, but suspended solids are not disposed of because of the presence of more easily oxidized substances in dissolved form. And growing on suspensions, they increase the weight of suspensions, due to the presence of mucus, they contribute to their biofloculation and good sedimentation properties. Consequently, the removal of suspensions from the desilter of the first stage should be greater than from the desilter of the second stage, since in the second stage, due to the vital activity of protozoa and small animals of the third trophic level, as well as partly the activity of heterotrophic bacteria eating out difficultly oxidized substances of suspensions, the concentration of suspended substances should decrease, albeit slightly. The sedimentation properties of the sludges of the first and second stages are almost identical, therefore, the dimensions of the modules are dictated exclusively by the loads on the sludge. And since the load on the sludge of the first stage should be no less than 5 times greater than on the sludge of the second stage, the module of the desilter of the first stage should be reduced by one and a half times in comparison with the module of the desilter of the second stage.

Figure 3 shows the effect of the flow velocity of the cleaned wastewater between the plates of the thin-layer module on the removal of suspended solids with clarified wastewater. If the flow rates of wastewater are equal at the first and second stage sludge separators, the removal of suspended solids from the first stage sludge separators will necessarily be greater than the removal of suspended solids from the second stage sludge separators, therefore, in the first stage the sludge concentration will necessarily be lower than the concentration of sludge in the second stage. And, therefore, the ratio of loads on the sludge of the first and second stages will always be respected.

The first stage is made by an ideal mixer because it is advisable to dilute the portion of the incoming water as quickly as possible with a short duration of the wastewater stay in the stage, reduce the toxicity present in it, and thereby create favorable conditions for the life of heterotrophic bacteria. The second stage, on the contrary, should be performed as a displacer as much as possible, since it must undergo denitrification processes involving heterotrophic bacteria - denitrifiers (in this zone, a minimum concentration of dissolved oxygen must be maintained in water) and nitrification processes involving autotrophic bacteria (in this zone in water, it is necessary to maintain the concentration of dissolved oxygen not lower than 4 mg O ₂ / l), and the processes of bacteria eating up the simplest. For this, the second stage is divided by a longitudinal partition into a long corridor with transverse circulation of the sludge mixture due to the special arrangement along the bottom of the aeration bubblers and a nozzle for holding nitrificators. In the mixer at the same time all the requirements for the working conditions of microorganisms of various directions cannot be created. Neither the first nor the second steps of the bioreactors provide for the removal of incremental sludge biomass for condensation and dehydration, since the sludge still contains a lot of organic substances, the ash content of the suspension does not exceed 30%, they rot during the day.

Meanwhile, when biomass moves along trophic levels, there is no loss of biogenic elements included in the structure of protein substances of microorganisms, phosphorus loss is observed when hydrolytic bacteria that feed on activated sludge biocenosis in aerobic mineralizers, or in digesters or other modifications of anaerobic bioreactors, are involved.

The nozzle in the second stage is necessary to hold slowly growing nitrifying agents.

The third stage should be performed one third more than the first one, and it is necessary to have a displacer because it is necessary to ensure the suspension of suspended sludge from the second stage, their mineralization by filtering sedimentators, and the transportation of feces and pseudo-faecals of these hydrobionts to the bottom of the tank in the third stage.

If the third stage is not a displacer, then there will be no guarantee that all three stages will proceed sequentially, non-mineralized sludge particles can immediately come to the tray for the treatment of treated wastewater from the third stage, that is, this is an obvious condition, but the size of the stage and the form of placement of the fibrous nozzle, making stage displacer, justified on the basis of testing a large number of options for technical solutions for placing nozzles and creating conditions for the active life of hydrobionts - sedimentators. The density of planting of hydrobionts on the fiber nozzle, the intensity of circulation of the wastewater being cleaned due to the organization of air flows in parallel with the curtains of the nozzle, the number of curtains was commensurate with the number of suspended solids purchased with drains per day, and this served as the basis for choosing the ratio.

Simplification of the operation of the treatment plant is achieved by the fact that the sludge is removed from only one stage and no longer needs additional mineralization.

The reduction in the volume of capacitive structures is achieved through the use of three stages and thin-layer sludge separators and the elimination of a precipitating mineralizer.

The reduction in energy costs was achieved by reducing the need for air due to the lack of a separate mineralizer for sewage sludge.

Sources of information

1. Engineering equipment of buildings and structures. Encyclopedia. Editor-in-chief Yakovlev S.V. M .: Stroyizdat, 1994, p. 453-456.

2. Patent RU 2183592, IPC C 02 F 3/02, publ. 2002.

Claims (1)

Biological wastewater treatment plant, including a tank divided by partitions into steps and sections, and bioreactor stage compartments, communication systems for supplying, distributing and discharging wastewater, sludge recirculation, air supply, thin-layer pulsed sludge separators, fiber nozzle for holding hydrobionts, communications for removing sewage sludge from a treatment plant, characterized in that the tank is made in three stages with different-sized steps, the second stage being twice as large e first, and the third step is one third more than the first; the first and second stages are equipped with compartments of thin-layer pulsation sludge separators, while the dimensions of the thin-layer pulsation sludge separator in the first stage are one and a half times smaller than in the second stage; in shape, the first stage is made by an ideal mixer, and the second and third stages are largely displaced; the nozzle is placed in the second and third steps; communications for the removal of sewage sludge outside the installation are provided exclusively in the third stage.

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