RU2326819C1 - Method of treating flush water from water-treatment stations - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: flush water is channelled into a storage tank, and then later pumped into a precipitation tank for separation of the given water into a deposit, directed for recycling, and the cleaned water. Into the storage tank, flush water is channelled, which would have formed in a period of four minutes from the beginning of washing the filters and/or clarifiers of the water treatment plant. Pumping through the pipeline is done at speed of the stream of 2-5 m/s. The pipeline is spiral shaped, and the time the water spends in the precipitation tank is about 30-50 minutes. In the pipeline there are about 6-22 field sources at a distance of 0.4-2.5 m from each other. The distance is measured on the length of the spiral pipeline stretched into a straight line. The field sources are used for treating the flush water through a constant electrostatic field with intensity of 4-20 kV/m when the flush water is being pumped in the pipeline. The field sources are shielded from the flush water.

EFFECT: obtaining of clear water and a deposit with low moisture without use of reagents; lower consumption of electrical power; reduction of the number of technological operations and reduction of labour expenditure of service personnel; lowering of the surface area of the treatment facilities.

4 ex

Description

The invention relates to methods for treating wash water of water treatment plants. The developed technology can be used to purify wash water from filters and / or clarifiers at water treatment plants.

Environmental protection is one of the main challenges facing humanity in this century. The invention allows to improve the quality of the treated wash water, namely to clean them by removing contaminants, with simultaneous partial disinfection.

Currently, the washing water of the filters of water treatment plants in many cities of Russia with the precipitation formed during the treatment process is discharged into open water bodies. This leads to pollution of water sources and a rise in the cost of drinking water treatment at water treatment plants in cities located downstream with a decrease in the quality of purified drinking water.

As a result of this effect of the wash water of water treatment plants, more and more water bodies are eutrophied due to a sharp increase in the concentration of pollutants over a considerable length of the river downstream from the place of release. Exceeding the load on organic pollution and heavy metals over the barrier performance of water treatment facilities in cities and especially small populated areas can lead to drinking water that does not meet the normative indicators of drinking water supply.

Therefore, for each water treatment plant, it is necessary to determine the technological scheme for washing water, depending on the quality of the source water and the composition of the treatment facilities.

The study of this problem at the beginning of the 21st century showed that in the scientific and technical literature there are practically no publications developed at state research centers and implemented at water treatment plants in Russia, technical and technological solutions [Draginsky V.L., Alekseeva L.P. Problems of water purification at water treatment plants in Russia // Water supply and sanitary equipment. 2006, No. 7, p.2-7]. This is mainly due to the fact that leading specialists in this area have left research institutes, which over the 90s of the 20th century have reorganized and are mainly engaged in commercial activities. In this regard, the urgency of the problem for many water treatment plants is a reality and a requirement of the current situation regarding the need to comply with the legislation of the Russian Federation in the field of public health, which leads to the development of washing water treatment technologies and the creation of domestic equipment.

An example of solving this problem in a separate enterprise is AvtoVAZ OJSC (Togliatti), where they tested in the laboratory and then introduced the well-known coagulation technology with aluminum polyoxychloride at the water treatment station [Pochitalin NP, Mineeva N.R. et al. Coagulant "AQUA-AURAT ^™ 30" in the reuse system of water "AvtoVAZ" Tolyatti // Water supply and sanitary equipment. 2006, No. 8, p.29-31]. At the treatment facilities, coagulant "AQUA-AURAT ^™ 30" was tested. This is due to the fact that, according to the project of the fourth stage of water treatment facilities, the return of washing water led to a change in the physicochemical characteristics of the coagulation and sedimentation processes in the settlers. As a result, the content of suspended solids in the water increased, which led to the supply of low-quality drinking water by a pumping station of the second rise.

Production tests of the coagulant in the presence of a flocculant of moderate degree of anionicity “Praestol 2515” revealed the peculiarities of dosing of these reagents at this station. It is better to dose the coagulant before the mixer, and the flocculant after the mixer. At this water treatment plant, this feature of using reagents allowed to increase the efficiency of coagulation and sedimentation of suspended solids.

The disadvantage of this method is the formation of a large volume of sludge containing high concentrations of aluminum-coagulant or iron compounds and high molecular weight organic flocculant substances, which are practically not utilized in sewage treatment plants, but require only dehydration and disposal, that is, deliberate contamination of certain soil areas near cities.

A known method of electric treatment of liquids, including processing them with a constant field in a dielectric capacitance by bipolar electrodes separated by a partition, which is used as the bottom of the tank, under which one of the electrodes is installed. The liquid is isolated from electrical contact by an additional dielectric partition located in the container above the liquid, while the second electrode is installed above the additional partition, and the material is introduced into the liquid to be treated in the solid dispersed state (RU 2226509, class С02F 1/48, published on 04/10/2004 )

However, in this patent there is no indication that the method described therein can be applicable for the treatment of wash water from water treatment plants, and this patent also describes a periodic design, sorbent additives are necessarily introduced, an air layer is required above the water surface, which reduces the effect electric field, which is associated with a voltage increase of 10-12%.

In the claimed invention, we used a continuous design, no additives are introduced, that is, we do not change the mineral composition of the wash water, we used the full filling of the pipeline with an aqueous medium.

The closest analogue of the claimed invention is the copyright certificate of the Russian Federation SU 1125207, cl. С02F 1/52, publ. 11/23/1984, bull. No. 43, from which a method for treating wash water of water treatment plants is known, providing that the wash water is sent to a storage tank and then to a water treatment plant. The installation includes a housing, the lower part of which is connected to the wash water supply pipe on which the ejector is mounted. In the upper part, the housing is equipped with a clarified water discharge pipe and an excess flake discharge pipe. The flocculant solution is introduced into the purified water through another pipeline.

The wash water is sent to the lower part of the housing through the wash water supply line. The flakes contained in the wash water, when it moves in the upward direction, are weighed and, gradually accumulating, form a layer of suspended flakes. Wash water passing through the specified layer is clarified by separating the sludge, and its excess is transferred to the settling tank to drain the excess flakes to sediment to separate these waters into the sludge sent for disposal and purified water.

The disadvantage of this method is the use of flocculant reagents, there is no treatment of wash water with a constant electrostatic field, which is associated with large labor costs.

The objective of the invention is the purification of wash water at water treatment plants to obtain clarified and partially disinfected water that can be discharged into open water and compacted sludge with minimal moisture without the use of reagents, with the introduction of energy-saving technology with minimal labor.

This object is achieved in that a method of treating wash water of a sewage treatment plant, comprising washing water being sent to a storage tank, and then pumping it through a pipe to a sump to separate said water into a sludge sent for disposal and the purified water according to the invention that the washing water is sent to the storage tank, which is formed within four minutes from the start of washing the contents of the filters and / or clarifiers of the water treatment plants, the water supply is carried out at a flow rate of 2-5 m / s, and the pipeline is helical, and the residence time of the water in the sump is 30-50 minutes, while on the pipeline at a distance of 0.4-2.5 m from each other, measured in length straight to a spiral-shaped pipeline, from 6 to 22 sources of electrostatic field are used in series, used to treat the wash water with a constant electrostatic field of 4-20 kV / m during their pumping through the pipeline, and these sources of electrostatic fields are isolated from wash water.

The technical result achieved due to the specified set of features is to obtain clarified water with chemical indicators that correspond to the norms of discharge of fishery reservoirs, sediment with low humidity, without the use of reagents, low electricity consumption, reduction in the number of technological operations, and as a result, reduction of labor costs attendants, reducing the area for treatment facilities.

At present, water treatment plants in many cities dispose of filter water without treatment in rivers. Wash water contains high concentrations of suspended solids, iron compounds and bacterial contaminants. This serious problem faces a large number of water treatment plants in Russia.

Therefore, cleaning and maximum reuse of wash water is necessary. The operating services, recognizing the importance and relevance of this problem, are conducting work on testing technological methods and constructive developments in the process of cleaning wash water from filters that can protect water bodies from technogenic loads. An analysis of the values of the controlled parameters of washing water by minutes of washing shows that high concentrations of suspended solids, heavy metals and bacterial contaminants are trapped on filters and clarifiers of water treatment plants, which enter the discharge pipelines in the first four minutes from the start of sludge washing.

Therefore, it is necessary to direct the washing water in the first four minutes from the start of washing the filters into the storage tank and then for cleaning. Further volumes of washing water do not contain high concentrations of heavy metals and bacterial contaminants, so they can be sent in accordance with the project to the beginning of the water treatment process or discharged into open water without treatment.

This allows you to interrupt the dispersion of suspended matter and the accumulation of heavy metals in treated water at stations where the wash water is sent for reuse, and for stations with the discharge of wash water into water bodies, reduce the volume of treatment facilities and use effective new technologies for cleaning wash water.

Wash water treatment, according to the developed technology, occurs due to the polarization of water molecules, enlargement of agglomerates of iron compounds, increase in the rate of adsorption of heavy metals on the alluvial layer and in the bulk of the loading material as a result of the effect of a constant electrostatic field on pollution containing complex metal compounds with variable valencies. The effect of disinfection was obtained experimentally and was controlled by the indicators "Total microbial number" (TBC) and E. coli.

During electrostatic treatment of wash water, processes of purification and partial disinfection take place.

The effect of a constant electrostatic field is manifested on the wash water flowing through the pipeline (flow rate of wash water 2-5 m / s).

Studies have shown that the aftereffect or the time during which water retains bactericidal properties when using the claimed method is more than 4 hours.

When exposed to a constant electrostatic field, the practical energy consumption is “zero” without taking into account the electricity consumed by the pumping equipment. The described method, using the effect of physical fields on the aquatic environment, has a significant advantage over any other non-reagent methods.

With a total salinity of water of less than 2.1 g / l, this design can be considered a capacitor with an inhomogeneous dielectric (see Elementary Physics Textbook, Volume 2, edited by Acad. Landsberg G.S. M .: Nauka, 1985, p. 76- 78). In the capacitor at any field strength below the electrical breakdown, the current is “zero”, therefore, the energy consumption is equal to “zero”.

Moreover, in order to achieve the technical result set by the applicant, it is important to influence the washing water with a constant electrostatic field of exactly 4-20 kV / m. It is economically unprofitable to set a greater value of tension, since this is associated with an increase in the cost of technical solutions, and as a result, an increase in the cost of cleaning. With a lower value of tension, the processing efficiency decreases sharply, which is impractical. When exposed to washing water, for example, containing petroleum products, of a constant electrostatic field of 4-20 kV / m, the formation of peroxide organic compounds occurs.

The flow rate of wash water 2-5 m / s is determined taking into account the stable cleaning effect of the currently widely used pumping equipment and energy costs by consumers. It is impractical to establish a high flow rate of the liquid medium, since the exposure time will be too short (for example, about 0.1 s), which will be insufficient for cleaning and disinfecting the wash water.

The pipeline, made in a spiral shape, with 6 to 22 field sources installed on it, ensures a compact structure, increases the degree of control of equipment operation, and reduces the cost of manufacturing and installation.

To achieve the maximum effect of clarification, it is necessary to maintain the flow rate in the pipeline through sources of a constant electrostatic field of 2-5 m / s with a duration of gravitational settling in the sump in the range of 30-50 minutes. An increase in the flow rate leads to a significant dispersion of iron oxide particles, which practically do not settle in the settling tank with a settling time of 30-50 minutes.

And at a flow velocity of less than 2 m / s, the required degree of consolidation of the sediment is not achieved, humidity increases and, as a result, its volume, which is not economically feasible.

It was found that the bacterial suspension in the washings is firmly fixed to mineral particles and is removed by sedimentation during gravitational sedimentation. A constant electrostatic field at a flow velocity of less than 2 m / s, acting on the structure of hydrated water penetrating the agglomerates of bacterial communities, causes a weakening of adsorption bonds with the surface of mineral particles. This leads to the occurrence of the desorption process in the volume of the medium and, as a consequence, to an increase in the TMP in clarified water. The passage of wash water through 6-22 field sources before entering the sump leads to a significant decrease in sediment volume.

The results of chemical analyzes of clarified water show that in order to obtain the maximum effect of extracting mineral suspension and bacterial contaminants from washing water, it is inexpedient to pass water through sources of a constant electrostatic field less than 6 times. Depending on the presence of organic complex compounds with heavy metals and oil products in the wash water, the number of field sources with a total salt content of the wash water of not more than 2.2 g / l varies from 6 to 22 pieces.

The distance between the field sources in the range of 0.4-2.5 m is determined by both the required degree of purification and the technical characteristics of the structure.

A decrease in the distance between the field sources less than 0.4 m leads to a field distortion and a decrease in the efficiency of the cleaning process. An increase in the distance between field sources of more than 2.5 m leads to a significant increase in the volume of the structure and, as a consequence, an increase in labor costs during operation.

An electrostatic field is a special case of an electric field (a stationary electric field created by fixed charges). An electrostatic field is created by motionless charges and does not change with time. The source of a constant electrostatic field is a motionless body or particle with a charge. The most effective are two parallel plates. In the claimed invention, the source of a constant electrostatic field is two stationary insulated plates having a charge and representing a capacitor.

The invention is carried out as follows.

The studies were carried out on the wash water from filters and / or clarifiers operated at water treatment plants, which made it possible to use the technology of the effect of a constant electrostatic field on the wash water to increase the efficiency of extraction of mineral suspended matter, heavy metals and bacterial contaminants in sedimentation tanks with a significant reduction in the amount of sludge formed.

The complex of facilities for the treatment of washing water consists of two tanks - a storage tank and a sump.

The wash water generated within four minutes from the start of the washing of the contents of the filters and / or clarifiers of the water treatment plants is sent through a pipeline to a storage tank. The process of rinsing water flows continuously. The contents of the filters and / or clarifiers of the water treatment plants include a solid phase and a colloidal phase. Wash water is pumped from the storage tank by a pump at a flow rate of 2-5 m / s through a spiral-shaped pipeline to a sump. From 6 to 22 field sources used to treat the wash water with a constant electrostatic field of 4-20 kV / m during pumping through the pipeline are successively installed on the pipeline at a distance of 0.4-2.5 m from each other. The distance between the field sources, equal to 0.4-2.5 m from each other, is measured as if the pipeline, made spiral, extend along its length in a straight line, that is, along the length of a spiral-shaped pipeline extended into a straight line. The specific number of field sources depends on the chemical composition of the wash water and the discharge requirements for treated water. The indicated field sources are isolated from the wash water. The total time of the field treatment of wash water in one source of a constant electrostatic field does not exceed 10 seconds. Accordingly - in 6-22 sources - does not exceed 60-220 seconds.

The presence of compounds of iron, manganese and other heavy metals increases the efficiency of cleaning wash water and helps to accelerate the extraction of contaminants from the aquatic environment. A high concentration of microorganisms, including pathogenic forms, adsorbed on the surface of the sediment, when using this technology is removed from the wash water.

After treatment in a constant electrostatic field, the wash water is sent to the sump for 30-50 minutes.

Impurities containing iron compounds and other heavy metals, after passing through a constant electrostatic field, enlarge and quickly settle in the settling zone to the bottom of the structure, from where they are sent for dehydration and disposal.

Thus, in the sump, these waters are separated into sediment, which is sent for disposal, and purified water, which is discharged into an open reservoir. The purified water complies with the norms of discharge into fishery water bodies.

The content of the COD value is reduced by 55-63% compared to the initial data, and the disinfection effect is at the level of 68-94% according to the TBC and E. coli, depending on which water body the water comes to the water supply station.

The invention is illustrated by the following examples of its implementation.

Example 1

The studies were carried out on wash water from clarifiers and quick granodiorite filters operated at a water treatment plant in the city of Angarsk.

Serve for processing water from the Angara River.

The wash water generated within four minutes from the start of the washing of the contents of the filters and clarifiers of the water treatment plant is sent through a pipeline to a storage tank. Wash water is pumped from the storage tank by a pump at a flow rate of 5 m / s through an outgoing spiral-shaped pipeline to a sump. On the outgoing pipeline, 12 field sources are used in series at a distance of 0.5 m from each other, used to treat the wash water with an electrostatic field of 4 kV / m during pumping through the pipeline. The distance between the field sources is measured as if the pipeline, made spiral, extend along its length in a straight line, that is, along the length of the spiral-shaped pipeline extended into a straight line. The indicated field sources are isolated from the wash water. The total time the field treats the wash water in one field source is 8 seconds.

After treatment with a constant electrostatic field, the wash water enters the sump for 50 minutes.

Thus, in the sump there is a gravitational separation of these waters into sediment, which is sent for disposal, and purified water that meets the standards for discharge into fishery reservoirs.

The total salt content of the washings was in the range of 0.4-0.6 g / l. The degree of disinfection according to E. coli corresponded to 84-92%, according to the indicator "TBC" - 90-94%. At the same time, purification from iron compounds was 90-96%, copper - 80-87%, manganese - 83-91%, zinc - 76-84% of the initial content.

Example 2

The studies were carried out on wash water from clarifiers operated at a water treatment plant in the city of Angarsk.

Serve for processing water from the Angara River.

Wash water generated within four minutes from the start of washing the contents of the clarifiers of the wastewater treatment plant is sent through a pipeline to a storage tank. Wash water is pumped from the storage tank by a pump at a flow rate of 2 m / s through an outgoing spiral-shaped pipe to a sump. On the outgoing pipeline, 6 field sources are used to be sequentially installed at a distance of 1 m from each other, used for treating the wash water with an electrostatic field of 20 kV / m during pumping through the pipeline. The distance between the field sources is measured as if the pipeline, made spiral, extend along its length in a straight line, that is, along the length of the spiral-shaped pipeline extended into a straight line. The indicated field sources are isolated from the wash water. The total time the field treats the wash water in one field source is 9 seconds.

After treatment with a constant electrostatic field, the wash water enters the sump for 45 minutes.

Thus, in the sump there is a gravitational separation of these waters into sediment, which is sent for disposal, and purified water that meets the standards for discharge into fishery reservoirs.

The total salt content of the washings was in the range of 0.4-0.6 g / l. The degree of disinfection according to E. coli corresponded to 84-90%, according to the indicator "TBC" - 92-96%. The purification from iron compounds was 92-96%, copper - 85-93%, manganese - 85-94%, zinc - 79-87% of the initial content.

Example 3

The studies were conducted on wash water from ion-exchange filters operated at a water treatment plant of an industrial enterprise.

Water is supplied for processing from an artesian well 90 m deep near the city of Tver.

The wash water generated within four minutes from the start of the regeneration of the filters of the water treatment plants is sent through a pipeline to a storage tank. From the storage tank they are pumped at a flow rate of 2.5 m / s through the outgoing pipe, made spiral-shaped, into the sump. At the outlet pipeline, 8 field sources are used in series at a distance of 0.4 m from each other, used to treat the wash water with an electrostatic field of 12 kV / m during pumping through the pipeline. The distance between the field sources is measured as if the pipeline, made spiral, extend along its length in a straight line, that is, along the length of the spiral-shaped pipeline extended into a straight line. The indicated field sources are isolated from the wash water. The total time the field treats the wash water in one field source is 6 seconds.

After treating the wash water with a constant electrostatic field, they are pumped into the sump for 30 minutes.

Thus, in the sump, these waters are separated into sludge, which is sent for disposal, and purified clarified water, which is sent to the recycled water supply system.

The total salt content of the wash water was 0.2-0.6 g / L. Purification by iron compounds reached 92-98%, mineral suspensions (Mn, W, Mo) - 90-96%, oil products - 72-80% of the initial content. The degree of disinfection according to E. coli is 82-89%, according to the indicator "TBC" - 72-84%.

Example 4

The studies were carried out at the general sewage treatment plant with mechanical filters and filters using membrane technology, operated by the food industry.

Serve for processing water from the Pirogovsky reservoir.

Wash water is piped to a storage tank. From the storage tank they are pumped at a flow rate of 3 m / s through the outgoing pipe, made spiral-shaped, into the sump. On the outgoing pipeline, 9 field sources are successively installed at a distance of 1.2 m from each other, used for treating the wash water with an electrostatic field of 10 kV / m during pumping through the pipeline. The distance between the field sources is measured as if the pipeline, made spiral, extend along its length in a straight line, that is, along the length of the spiral-shaped pipeline extended into a straight line. The indicated field sources are isolated from the wash water. The total treatment time of the wash water by an electrostatic field in one field source is 10 seconds.

After treating the wash water with a constant electrostatic field, they are pumped into the sump for 40 minutes.

Thus, in the sump there is a gravitational separation of these waters into sediment, which is sent for recycling, and purified water for reuse in technological processes.

The total concentration of salinity in the wash water is in the range of 0.8-1.1 g / l. Achieved total purification from suspended solids at the level of 87-96%, heavy metals - 82-90%, depending on the concentration of organic pollutants. The degree of disinfection according to E. coli is 84-90%.

Thus, the proposed invention allows you to effectively treat wash water to a high degree of purification and disinfection.

Wash water treated by the proposed method using the specified sequence of operations and their parameters have better characteristics compared to the closest analogue.

Claims (1)

A method of treating wash water of a sewage treatment plant, comprising washing water being sent to a storage tank, and then pumping it through a pipe to a separator for separating said water into a sludge to be disposed of, and purified water, characterized in that the washing water is sent to the storage tank formed within four minutes from the start of washing the contents of the filters and / or clarifiers of water treatment plants, piping is carried out at a flow rate of 2-5 m / s, and piping d is made spiral, and the residence time of the water in the sump is 30-50 minutes, while on the pipeline at a distance of 0.4-2.5 m from each other, measured along the length of a straight spiral pipe, from 6 to 22 sources are installed in series electrostatic fields used to treat the wash water with a constant electrostatic field of 4-20 kV / m strength during their pumping through the pipeline, and these field sources are isolated from the wash water.