RU2377192C1 - Method for biological decontamination of treated waste waters - Google Patents

Abstract

FIELD: water supply.

SUBSTANCE: invention may be used for protection of biocoenosis. Out of structures of biological treatment of drainages, water along pipeline 1 is supplied to device 2 of ultraviolet radiation (UVR). Service tank 5 with the help of pump 7 is filled with purified waste liquid, and due to tangential input of pipeline 6, microbiological preparation is mixed to waste fluid. Out of service tank 5, mixture of microbiological preparation with treated fluid is sent to mixer 4, where it is mixed to the main volume of waste waters, which also come to mixer 4 from device 2 of UVO. Then along 8 treated liquid is sent to conical part of bioreactor 10, simultaneously providing for its distribution with the help of reflector 9. If relatively even flow of the whole volume of waste water is maintained through nozzle 11, most complete contact of their waste waters is provided with immobilised microorganisms. Water treated in bioreactor 10 is discharged into water object along pipeline 14. Residue accumulated in lower conical part 12 of bioreactor 10 is periodically drained along pipeline for recycling into system of residue treatment.

EFFECT: invention makes it possible to provide for reliable protection of water objects biocoenosis, to simplify technology of drainage decontamination and to improve conditions that affect public health.

1 cl, 1 dwg

Description

The invention relates to wastewater disinfection using microbiological treatment and can be used at the last stage of their treatment before discharging effluents into water objects to protect the biocenosis of these objects by eliminating toxic and mutagenic substances from entering them, as well as by preventing uncontrolled development of undesirable microflora.

A known method of disinfection of wastewater for the destruction of potentially pathogenic and pathogenic microflora - pathogens of infectious diseases, which consists in introducing chlorine water or chlorine-containing components (a biologically active agent that destructively affects microorganisms) into the treated wastewater in front of the contact reservoir in an amount (by active chlorine) up to 3 g / m ³ after complete biological treatment, stirring the mixture, keeping it in the tank for 30 minutes, providing a coli titer to the limit x 0.001, followed by the release of the treated liquid into the water body through devices that provide intensive dilution (Laskov, Yu.M. et al. Examples of calculations for sewer structures: Textbook for universities / Yu.M. Laskov, Yu.V. Voronov, V . I. Kalitsun. - 2nd ed., Revised and enlarged. - M.: Stroyizdat, 1987. Pp. 194-196).

The disadvantage of this method is the low efficiency of protecting the biocenosis of water bodies, which is caused by the formation of compounds toxic and dangerous for the life of aquatic organisms, which lead, inter alia, to their death and have even greater negative consequences than discharge of non-chlorinated wastewater. In particular:

- when organochlorine waters are chlorinated, organohalogen compounds are formed, and the most dangerous of them are trihalogenomethanes, among which the formation of chloroform is most likely, and toxic compounds can accumulate in bottom sediments and can affect the biocenosis of water bodies for a long time;

- chlorination also leads to the appearance of bromine-containing compounds (bromodichloromethane and dibromodichloromethane), which in some cases mainly determine the toxicity of the treated water and the active effect on the microbiocenosis of water bodies - wastewater receivers;

- during chlorination, the appearance of substances with high levels of genotoxic activity, such as chlorophenols, chlorobenzenes, carbon tetrachloride, and a number of others, is also likely.

The effect of disinfecting effluents can be significantly reduced due to the fact that, interacting with the organic component of the waste fluid, chlorine can participate in substitution, addition, or oxidation reactions and when a certain amount of ammonium salts is contained in this fluid, chloramines are formed, the bactericidal effect of which is many times weaker active chlorine. In this case, pathogenic microflora is not completely destroyed and can be quickly restored after the discharge of treated effluents into a water body. At the same time as “undesirable” microflora, non-pathogenic microorganisms are destroyed, the presence of which in the treated wastewater and in the water of a water body is necessary to maintain the overall microbial balance. It should also be borne in mind that if pathogenic and non-pathogenic microflora are not selectively destroyed in wastewater, the “clean” environment is very unstable and is quickly populated by the same or other types of microorganisms, often even more unfavorable. In water bodies (rivers, lakes, marine areas) new components of biocenoses appear that determine the levels of epidemiological processes in the environment that affect the health of the population.

In addition, it is widely known that when chlorinated wastewater that has undergone biological treatment is discharged into the river, organochlorine compounds, which are highly resistant, cause pollution at significant distances downstream and are practically not extracted during the intake of river water for household and drinking needs water treatment, fall into the distribution network. In this regard, regardless of the intensity of dilution of the treated effluents, it is not always possible to discharge them even with a residual standard amount of chlorine up to 1.5 mg / dm ³ .

The disadvantages of the use of liquefied chlorine in the disinfection of wastewater also include its toxicity, which determines high requirements for the qualifications of staff and strict adherence to safety regulations. Increased corrosion activity determines the complexity of a technological nature, in particular, the relatively rapid failure of equipment. With a relatively small productivity of the wastewater treatment system, in particular, with active chlorine consumption of less than 30-50 g / h, the requirements for metering accuracy increase, which also causes certain difficulties in the operation of LONII-100 units.

A known method of disinfecting wastewater, which consists in introducing at the last stage into the liquid to be treated the ozone synthesized in ozonizers, vigorously stirring with a bubbler and keeping the mixture in contact chambers with the utilization of residual ozone with subsequent discharge of the treated wastewater into a water body (Laskov Yu.M. and other Examples of calculations of sewer structures: Textbook for universities / Yu.M. Laskov, Yu.V. Voronov, V.I. Kalitsun. - 2nd ed., revised and additional - M .: Stroyizdat, 1987 P. 196-198).

The disadvantage of this method is the low effect of protecting the biocenosis of water bodies, due to the fact that the effect of ozone on the organic compounds contained in water does not create conditions for their complete elimination from liquid media, but modifies them with the formation of other organic substances, which can also have a negative effect on living organisms of water bodies - wastewater receivers. The reaction products of ozone with organic substances in water are believed to be aldehydes, ketones, carboxylic acids and other hydroxylated and aliphatic aromatic compounds. The phenomenon of the secondary development of pathogens that are cultivated in the aquatic environment, for example, in distributing water supply networks on biodegradable organic compounds formed during ozonation, is also possible. In addition, the practice of using ozone in the treatment of natural and wastewater for their disinfection reveals many difficulties similar to those encountered with chlorination. In particular, ozone is not less toxic than chlorine, it is explosive and significantly enhances corrosion processes, requires highly qualified and trained service and special safety measures. The toxicological safety of wastewater ozonation when released into a water body cannot be considered sufficient and in any case, the use of this method for disinfection of effluents must be carefully justified, including economically.

There are known physical methods of inactivating pathogens in aqueous media by destroying the genome of a bacterial cell or the nucleic acid of a virus, which include ultraviolet irradiation of the treated fluid stream in a special apparatus (Butin V.M. et al. Implementation of UV wastewater disinfection technology // Water supply and san. Technique. 1996. No. 12. P. 18-20).

The disadvantage of ultraviolet radiation for disinfection of treated domestic wastewater along with the high energy intensity of the method is the low efficiency of disinfection and protection of the biocenosis of water bodies, associated with the following:

- microorganisms in water can be immobilized on the components of suspended particles or located inside such particles, which protects them from direct exposure to ultraviolet rays;

- the presence of suspended matter in the effluent scatters directed radiation, reflecting it or shielding, thereby reducing the disinfecting effect and often only leads to a slowdown in the development of bacteria and some aquatic protozoa;

- the absence of the prolonged action of ultraviolet radiation, which is usually carried out in a special apparatus on flowing media, the effect of suppressing microflora becomes short-term and in this situation, when there is a sufficient amount of nutrient substrate in the water (organics, including oppressed and dead bacteria), re-colonization and restoration are stimulated microflora in the aquatic environment already with increased mutagenic activity, which means with a significantly changed species composition, which is negative and especially significant enno effect after reset drains into a water body.

The closest in technical essence and the achieved effect to the claimed solution is a known method of disinfecting treated wastewater, which includes introducing into the liquid to be treated at the last stage of purification of a biologically active agent - microorganisms that destroy microflora of potentially pathogenic and pathogenic - pathogens of infectious diseases, as biologically active the agent uses a microbiological preparation containing non-pathogenic microorganisms, a microbiological preparation at is introduced into the supply tank, which is preliminarily filled with the treated liquid, and maintained until the non-pathogenic microorganisms adapt to this medium, the supply tank is replenished with the treated waste liquid and microbiological preparation as this mixture is consumed, from the supply tank the mixture is introduced before the bioreactor into the wastewater supplied from sewage treatment plants, the bioreactor is equipped with a nozzle, on which they provide immobilization of non-pathogenic microorganisms.

The disadvantages of this method are:

- insufficient reliability of protection of water bodies from the removal of pathogenic and potentially pathogenic microorganisms in extreme situations, in particular, when the load changes by flow rate or pollutants, when the temperature and other conditions change, since in such cases it is difficult to regulate the flow rate of a microbiological preparation;

- complex preparation of the bioreactor, if necessary, preliminary populating the nozzle with non-pathogenic microorganisms;

- does not exclude the possibility of incomplete suppression of pathogenic or potentially pathogenic microflora present in the treated effluents with the possibility of development of a bioreactor on the nozzle, including undesirable types of microorganisms under sharply changing operating conditions of the bioreactor.

The objective of the invention is to create a new method of disinfection of wastewater, providing reliable protection of the biocenosis of water bodies, simplifying the technology of the process of disinfecting effluents and improving conditions affecting the health of the population in the places of release of treated wastewater by creating conditions for the active development of non-pathogenic microorganisms at the last stage of treatment, able to suppress pathogenic microflora and mineralize the organic matter contained in the treated effluents.

The specified problem is solved as follows.

In the known method of biological disinfection of treated wastewater, which includes introducing into the liquid to be treated at the last stage of purification of a biologically active agent - microorganisms that ensure the destruction of microflora of potentially pathogenic and pathogenic pathogens of infectious diseases, a microbiological preparation containing non-pathogenic microorganisms is used as a biologically active agent, microbiological the drug is introduced into a consumable container, which is filled with the treated liquid, and in It is kept until the adaptation of non-pathogenic microorganisms to this medium, the supply tank is replenished with the treated waste fluid and microbiological preparation as this mixture is consumed, the mixture is introduced into the waste water supplied from treatment plants before the bioreactor, the bioreactor is equipped with a nozzle on which the non-pathogenic microorganisms are immobilized , before the introduction of a microbiological preparation containing non-pathogenic microorganisms, ultraviolet irradiation is carried out with biological waters, and suppression of the vital activity of microorganisms contained in wastewater.

Distinctive feature of the prototype is:

- preliminary, before the introduction of a microbiological preparation containing non-pathogenic microorganisms, ultraviolet irradiation of wastewater that has undergone biological treatment is carried out, and the vital functions of microorganisms contained in wastewater are suppressed.

The indicated distinctive feature, namely: prior to the introduction of a microbiological preparation containing non-pathogenic microorganisms, ultraviolet irradiation of wastewater that has undergone biological treatment (for example, after secondary settling tanks) is carried out, and the vital functions of microorganisms contained in wastewater are suppressed, which ensures numerical superiority of non-pathogenic microorganisms . In this case, only non-pathogenic types of microflora are immobilized on the nozzle of the bioreactor, regardless of the order of administration of the drug and the filling of the system. In this case, complex preparation of the bioreactor is not required, there is no need to pre-populate the nozzle with non-pathogenic microorganisms that develop spontaneously in quantitative terms, and their number is regulated depending on the nutritional value of the medium (the content of organic matter in the treated liquid), temperature, and wastewater flow rate. The conditions for the development of non-pathogenic microorganisms on the nozzle of the bioreactor turn out to be more favorable, since energy is not required for species competition (only non-competing species are contained in the microbiological preparation). The possibility of incomplete suppression of the pathogenic or potentially pathogenic microflora present in the treated effluents before irradiating them in the UVD apparatus is excluded, since they are almost completely destroyed or suppressed before the introduction of non-pathogenic species into the waste fluid and only non-pathogenic microorganisms can develop on the nozzle of the bioreactor. This also makes it possible to reduce the consumption of a microbiological preparation containing non-pathogenic microorganisms, and, consequently, the content of organic material in the effluents supplied to the bioreactor and further to the water body is reduced. When wastewater is discharged into a water body (river, lake, sea), a microbiological niche does not form, along with treated effluents, only non-pathogenic microorganisms enter the water body, which does not cause any undesirable microflora to develop in it unpredictably.

Thus, a causal relationship between the distinguishing feature of the claimed invention and the achieved technical result is ensured: high efficiency and reliability of protecting the biocenosis of water bodies while simplifying the technology of disinfection of wastewater and improving conditions affecting public health when discharging treated wastewater into water bodies.

An example of industrial applicability of the invention.

The drawing shows a flow chart illustrating a method of biological disinfection of wastewater. The diagram shows a pipeline 1 through which the treated wastewater is supplied from biological wastewater treatment plants, in particular, from a secondary settling tank (not shown conventionally), an ultraviolet irradiation apparatus (UVD) of wastewater, a wastewater supply pipe 3 to the mixer 4, a supply container 5 for mixing a microbiological preparation with a liquid to be treated. Pipeline 6 with tangential entry into the supply tank 5 for supplying part of the treated wastewater. The sewage discharge pipe 8 from the mixer 4, equipped with a reflector 9 for uniform distribution of liquid in the lower part of the bioreactor 10, equipped with a mesh nozzle 11 and sediment collector 12 is the lower part of the conical bottom. The bioreactor 10 is equipped with an annular tray 13 for collecting the treated wastewater and a pipe 14 for discharging disinfected wastewater into a water body.

Pre-treatment of wastewater supplied from treatment plants, for example, from secondary sumps through pipeline 1, in the apparatus 2 of ultraviolet irradiation (UV). After this treatment, the microflora present in the wastewater is inactivated or suppressed, which is fed through line 3 to the mixer 4, which also receives a mixture of wastewater and microbiological preparation from the supply tank 5. The microbiological preparation (concentrate) is periodically supplied (shown by arrow) from the tank. The supply tank 5 through a pipe 6 with a tangential inlet, for example, using a pump 7, is filled with purified wastewater that has been processed in a UFD apparatus 2. As a microbiological preparation containing non-pathogenic microorganisms, for example, Vostok EM-1, ready to use, is used (Effective microorganisms: practical recommendations for the use of EM series products / comp. Severina V.Ya., Adamenko L.Ya. // Primorsky EM Center, - Vladivostok, 2002. Page 11). The indicated preparation contains various types of microorganisms, in particular, phototrophic and lactic acid bacteria, yeast, actinomycetes and enzyme fungi. Genetically modified microorganisms and pathogenic or potentially pathogenic microorganisms were not found in the preparation, since the preparation was created on the basis of strains of only non-pathogenic microorganisms. To ensure mixing of the microbiological preparation with the wastewater supplied by the pump 7 to the supply tank 5, the input of the pipeline 6 is tangential.

The required flow rate of the specified drug, which is fed from the tank into the supply tank 5, depends, in particular, on the concentration of organic matter, including nitrogen and phosphorus compounds in the waste fluid after complete biological treatment. At the same time, the concentration of the microbiological preparation in the supply container 5 should be at least 1.0-2.0%. When the wastewater is supplied to the tank 5, for example, due to the tangential introduction of the pipeline 6, the microbiological preparation is mixed with the wastewater. The organic matter contained in the wastewater, including microorganisms inhibited in apparatus 2 of the Ural Federal District, serves as a nutrient medium for non-pathogenic microorganisms and ensures their active development.

Initially, when the biological disinfection system is launched, the mixture of wastewater and microbiological preparation is kept in the supply tank 5 for at least 20-28 hours until the maximum increase in the number of non-pathogenic microorganisms and their adaptation to the environment - to the treated wastewater. In the study of water samples after contact of the microbiological preparation "Vostok EM-1" even with untreated sewage in the Ural Federal District for 20-28 hours according to the method MU 2.1.5.800-99, which is officially used to assess the effectiveness of wastewater disinfection (Organization of state sanitary and epidemiological surveillance for wastewater disinfection : Methodological instructions. - M.: Federal Center for State Sanitary and Epidemiological Supervision of the Ministry of Health of Russia, 2000. - 27 p.), The result can be considered quite satisfactory. Since the number of coliform bacteria, which are indicators of the presence of pathogens of bacterial intestinal infections, and coliphages, indicators of viral contamination, does not exceed the permissible limits (not more than 100 CFU / 100 ml). Therefore, in a mixture of a microbiological preparation and wastewater with microflora oppressed in the UFD apparatus 2, only non-pathogenic species present in the preparation supplied from the tank (shown by the arrow) can also be present in the supply tank 5. During this time, non-pathogenic microorganisms adapt to the nutrient medium - the liquid being treated and their number increases, which ensures the preferential development of only those types of non-pathogenic microorganisms for which this medium is most acceptable at the time of wastewater treatment.

From the supply tank 5, the mixture of the microbiological preparation with the liquid to be treated is fed into the mixer 4, where it is mixed with the main volume of wastewater, also entering the mixer 4 from the apparatus 2 of the Ural Federal District. The amount of the mixture of microbiological preparation and effluents, which is supplied from the supply tank 5, should be up to 5% of the total flow rate of the treated waste fluid. To ensure optimal living conditions of microorganisms in front of the mixer 4, the liquid is aerated, for example, by spraying. At high performance of the wastewater treatment system, aeration is also carried out by supplying air to the bioreactor 10. As the mixture is consumed, the supply tank 5 is replenished through the pipeline 6 with the treated sewage from apparatus 2 of the Ural Federal District and the microbiological preparation from the tank. From the mixer 4, through the pipeline 8, the processed liquid is supplied to the conical part of the bioreactor 10, it is evenly distributed (shown by arrows) over the cross-sectional area of the bioreactor 10, for example, by means of a reflector 9 mounted above the open end of the pipeline 8.

The bioreactor 10 is performed, for example, in the form of a cylindrical part — the working zone in which the mesh nozzle 11 and the conical bottom are installed. The nozzle 11 in the bioreactor 10 is performed, for example, from a fine-mesh nylon mesh (fishing case) by analogy with known solutions (Patents of the Russian Federation: No. 2157345; No. 2194672). At the same time, the height of the working zone of the bioreactor 10, with the mesh nozzle 11 located in it, is taken in the range of 1.5-2.0 m. A sediment accumulator 12 is arranged in the lower conical part of the bioreactor 10, from which the accumulated sediment is periodically removed.

When the treated fluid enters the bioreactor 10, an upward flow is formed in the working area of the bioreactor 10, in which the mesh nozzle 11 is placed. On the nozzle 11, only non-pathogenic microorganisms that are present in the microbiological preparation are immobilized and actively develop in the supply tank 5 and adapt to the conditions of the processed environment. The flow rate of the treated waste fluid in the working area of the bioreactor 10 is taken in the range of 10-15 m / h.

The immobilization of non-pathogenic microorganisms on the nozzle 11 of the bioreactor 10 allows you to create favorable living conditions for non-pathogenic microorganisms, in particular, to exclude the energy costs of their movement, since the microorganisms receive nutrients from the processed fluid flowing around them, which is a nutrient medium. At the same time, the immobilized microorganisms attached to the nozzle 11 receive additional advantages in relation to the undesirable microflora, which may appear during processing, since it is difficult to completely kill microorganisms in the apparatus 2 of the Ural Federal District, although most of them are suppressed. In this case, complex preparation of the bioreactor 10 is not required, there is no need to pre-populate the nozzle 11 with non-pathogenic microorganisms that develop spontaneously in quantitative terms, and their number is regulated depending on the nutritional value of the medium (the content of organic matter in the processed liquid), temperature, and wastewater flow rate. The conditions for the development of non-pathogenic microorganisms on the nozzle 11 of the bioreactor 10 are more favorable, since energy is not required for species competition (only non-competing species are contained in the microbiological preparation).

When a relatively uniform flow of the entire volume of wastewater through the nozzle 11 is formed, they provide the most complete contact with immobilized microorganisms. Non-pathogenic microorganisms attached to the nozzle 11 are in more favorable conditions and, as a result of exposure to other types of microorganisms contained in the waste fluid, reduce their numbers up to the complete destruction including potentially pathogenic and pathogenic microflora, which is determined by the principle known in the natural environment competitive exclusion (Gause law). The mechanism of suppression of competing types of microorganisms is determined by the fact that, having a numerical advantage, non-pathogenic microorganisms secrete specific enzymes and other metabolic products that are unacceptable for other species, which leads to their suppression. In addition, non-pathogenic microorganisms contained, for example, in the microbiological preparation "Vostok EM-1", are able to more actively mineralize the organic matter of the treated effluents and, thus, deprive unwanted bacteria of nutrition. This ensures not only disinfection of effluents, but also, which is most important from an environmental point of view, exclude toxic substances from entering the water body and, thus, ensure its effective environmental protection when discharging treated wastewater.

The water treated in the bioreactor 10 is diverted by an annular chute 13 located in the upper cylindrical part of the bioreactor 10, and is discharged through a pipe 14 into a water body — a wastewater receiver. The precipitate is accumulated in the lower conical part 12 of the bioreactor 10 and is periodically diverted through the pipeline for disposal to the sediment processing system.

Thus, pretreatment of wastewater in the UFD apparatus 2 excludes the possibility of incomplete suppression of pathogenic or potentially pathogenic microflora present in the treated effluents before irradiation in the UFD apparatus 2, since they are suppressed before the introduction of non-pathogenic species into the effluent and on the nozzle 11 of the bioreactor 10 can only non-pathogenic microorganisms develop. This reduces the consumption of a microbiological preparation containing non-pathogenic microorganisms, and, therefore, reduces the content of organic material in the effluents supplied to the bioreactor 10 and further to the water body. When wastewater is discharged into a water body (river, lake, sea), a microbiological niche does not form, along with treated effluents, only non-pathogenic microorganisms enter the water body, which does not cause any undesirable microflora to develop in it unpredictably. Therefore, using a new method of disinfection of treated wastewater provides reliable protection of the biocenosis of water bodies, simplifies the technology of the process of disinfection of effluents. At the same time, in places where treated wastewater is discharged into water bodies, factors that negatively affect the ecological state of the water body are eliminated, it does not cause dystrophy and harmful effects on the biocenosis, therefore, the likelihood of a negative impact on public health is also eliminated.

Claims (1)

A method of biological disinfection of treated wastewater, comprising introducing into the liquid to be treated at the last stage of purification of a biologically active agent - microorganisms that ensure the destruction of microflora of potentially pathogenic and pathogenic pathogens of infectious diseases, using a microbiological preparation containing non-pathogenic microorganisms as a biologically active agent, the microbiological preparation is administered in a consumable container, which is filled with the processed liquid, and can withstand adaptation of non-pathogenic microorganisms to this medium, the supply tank is replenished with the treated waste liquid and microbiological preparation as this mixture is consumed, from the supply tank the mixture is introduced before the bioreactor into the waste water supplied from treatment plants, the bioreactor is equipped with a nozzle on which the non-pathogenic microorganisms are immobilized, which differs the fact that before the introduction of a microbiological preparation containing non-pathogenic microorganisms, conduct ultraviolet irradiation s waste water passed biological treatment, and suppression of the activity of microorganisms contained in the wastewater.