RU2099294C1 - Method and apparatus for finely cleaning highly loaded waste waters - Google Patents

Abstract

FIELD: waste water treatment. SUBSTANCE: invention relates to high- efficiency physico-chemical and subsequent biological cleaning of highly loaded waste waters with complex composition, for example, filtrates running out from solid household waste dumps. Cleaning process consists of following stages: ammonia stripping, adjusting pH, electrocoagulation and electroflotation, filtration and simultaneously readjusting pH, UV treatment and biopurification, posttreatment in bio-lagoons. EFFECT: enhanced purification efficiency. 3 cl, 4 dwg , 4 tbl

Description

 The invention relates to the field of integrated physico-chemical and subsequent biological treatment of highly concentrated wastewater of complex composition, for example, industrial waste water, filtrates of landfills for solid household waste (MSW), and can be used in utilities and various industries. A characteristic feature of such drains is the content in them, along with organic and inorganic substances, of a large number of organometallic complex compounds, for example, compounds of heavy multivalent metals with amino acids or humic acids. Such compounds practically do not lend themselves to traditional methods of purification, since they do not precipitate due to their surface-active properties and are not destroyed by commonly used oxidation methods due to their high stability, but by biological methods because of their high toxicity. A significant complication of the cleaning process is also the high content of ammonia in the product effluent anaerobic processes.

 At the same time, landfills and landfills are today the most common method of landfill and occupy thousands of hectares in the country, and the effluents resulting from them, having high toxicity, adversely affect the environment, polluting ground and underground water sources.

 Given the high requirements for treated wastewater in accordance with the standards for discharge into the reservoirs of cultural, domestic and fishery water use, a comprehensive physico-chemical treatment in combination with aerobic and anaerobic biological treatment is recommended for purification of the filtrate.

 Known methods and installations for the treatment of heavily polluted effluents. In German patent (N 4116557, C 02 F 1/72, 1/70, 1992) it is proposed to treat waste water from waste paper processing plants according to a multi-stage scheme, including preliminary flotation, grinding and dissolution of a number of components with subsequent oxidation or reduction at elevated temperature . This scheme allows to reduce COD and to reduce the concentration of salts and colloidal particles. However, the intensity of treatment of complex complex effluents in this way is small and does not allow to bring their composition to parameters that meet the requirements when discharged into fishery reservoirs.

 In US patent (N 5139679, C 02 F 1/32, 1/72, 1992) it is proposed to treat the effluents by oxidizing them with hydrogen peroxide and a catalyst, followed by treatment with ultraviolet (UV) radiation. This method allows to increase the efficiency of irradiation, but does not provide complete decomposition of complex organic compounds and removal of inorganic components. In addition, pre-treatment does not provide discoloration of the runoff, which is necessary for effective UV irradiation.

 The German patent (N 4130340, C 02 F 1/78, 1/28, 1992) proposes to mix the purified water with the air enriched with ozone before UV irradiation. In this case, the water from the clarifier is purified by additional sorption on activated carbon and filtration. However, this method does not allow the sewage to be completely cleaned of organic contaminants (since filtration precedes irradiation) and has low efficiency with respect to inorganic substances dissolved in water.

 In US patent (N 5130032, C 02 F, 1/36, 1/32, 1/48) a method for purification of contaminated liquids by the sequential use of ozonation, exposure to a magnetic field and UV radiation. However, the lack of a biological treatment stage and the low intensity of UV irradiation do not allow this method to be used to clean the landfill filtrate.

 The closest in technical essence to the claimed technical solution is the "System of diversion and treatment of surface runoff" (Russian patent, N 1699954 A1, C 02 F 3/00, 1/00, 1991), by their consistent physico-chemical cleaning, consisting of pH adjustment and filtration, as well as bio-treatment. This method is adopted as a prototype. The reasons that impede the achievement of the required technical result when using this well-known technical solution include the lack of a system that allows for intensive energy exposure to complex components of the runoff that are not amenable to direct bio-treatment, and, accordingly, to destroy them prior to bioremediation. In addition, the direct use of only one pH adjustment, proposed in the prototype solution, does not allow to effectively implement the electrocoagulation and biological treatment operations in a single technological cycle, since different acidity of the solution is necessary for their implementation.

 The invention proposed in this application is directed to the development of a universal method for deep treatment of heavily contaminated wastewater using physicochemical and biological methods, which allows to neutralize effluents characterized by high toxicity, the content of significant concentrations of humic acids, multivalent metals, surfactants and other types of pollution .

The invention consists in the following. Deep treatment of heavily contaminated wastewater, including physico-chemical and biological treatment, is carried out by the sequential use of the stages:
distillation of ammonia;
pH adjustments
electrocoagulation;
electroflotation;
active filtration with repeated adjustment of pH;
UV treatments;
anaerobic and aerobic treatment with post-treatment in biological ponds.

 As a result of the invention, due to a certain sequence of operations and features of the processes of adjusting the pH and UV irradiation, complete purification of heavily contaminated effluents is achieved to parameters that satisfy the requirements for discharge into fishery reservoirs.

 The specified result in the implementation of the invention is achieved by the fact that in the method of deep purification of highly contaminated wastewater containing the stages of physico-chemical treatment, including pH adjustment, filtration and biological treatment, at the stage of physico-chemical treatment before the first pH adjustment, ammonia is distilled off, and then electrocoagulation and electroflotation, then filtering and UV treatment. In this case, the pH adjustment is carried out twice: before electrocoagulation and before UV treatment, combining the process of the second pH adjustment with filtering on a mineral filtering agent, which ensures the combination of clarification and pH adjustment operations.

 An additional feature of the proposed method is that the UV treatment is carried out using a xenon flash lamp having a continuous emission spectrum in the wavelength range of 200-2000 nm and peak power in the ultraviolet range of 150-250 kW. The irradiation intensity is adjusted by setting the number of pulses per unit time.

 In FIG. Figure 1 shows the frequency characteristics of mercury and xenon lamps in the UV range, which confirm the advantages of the latter in both intensity and frequency capabilities. A comparison of these data with FIG. 2, which shows the absorption spectrum of an aqueous phenol solution, allows us to conclude that the xenon lamp is clearly superior to mercury in the case of resonant destruction of phenol molecules.

 An additional advantage of a xenon lamp is its ability to destroy not only complex molecules, such as phenol, but also products formed in the first stage of phenol destruction; relevant data are shown in figure 3 and in table 1.

 A distinctive feature of the use of UV radiation for water treatment is the dependence of the processing efficiency on its transparency. The higher the turbidity or color of the initial solution or suspension, the shorter the light flux attenuation occurs from the source and, accordingly, the irradiation efficiency decreases. In this case, light energy is not spent on the resonant destruction of organic molecules, but on scattering.

 Therefore, before applying the cleaned liquid for UV treatment, it is necessary to lighten it to the maximum extent. Table 2 shows how complex aliphatic and aromatic hydrocarbons are destroyed under the influence of a flash xenon lamp.

*) Note to table 2: the initial concentration of substances was, respectively, (10 ^-2 mg / l): 5; 9.8 and 14.7.

 The complex composition of the filtrate contaminants necessitates the use of a complex process stream, including a number of sequential operations, for its deep cleaning.

 In accordance with the flowchart shown in FIG. 4, the filtrate coming from the drainage system of the landfill is sent to a receiving tank 1, which ensures its uniform flow to the deep cleaning unit. From the receiving tank, the filtrate is pumped by pump 2 to apparatus 3, where ammonia is partially distilled off. From apparatus 3, the filtrate flows by gravity into apparatus 4 to adjust the pH. Compressors 5 are supplied with air 5 to devices 3 and 4 to distill off the ammonia and mix the solution while adjusting the pH.

 Hydrochloric acid, used to adjust the pH of the filtrate, is transferred from the railway tank with a compressor 5 to the receiving tank 6. From the tank 6, the acid is transferred to the supply tank 7, from where it enters the apparatus 4. The amount of incoming acid is regulated by the pH control system in the apparatus. PH adjustment occurs as the machine fills. To ensure continuous operation of the process stream, two devices are installed in parallel, in one of which the pH is adjusted, and from the second, the filtrate that has passed this operation is pumped continuously to the electroflotator 9 by pump 8.

 In the electrocoagulative part of the apparatus (with consumable electrodes), dissolved inorganic (mainly containing heavy metals) and, in part, organic impurities are precipitated from the filtrate. Part of the coagulated substances forms a slurry that is removed from the apparatus through the lower flange. After coagulation and separation of the precipitate, the purified water is sent to electroflotation. The peculiarity of this process in the proposed scheme is associated with the presence in the source water, as a rule, of a large number of organic compounds with surface-active properties, which allows the electroflotation process to be carried out without the introduction of flocculants and floating agents. In the absence of such compounds in the wastewater, appropriate agents may be added to it.

 The sludge is discharged and sent for burial to a special repository 10. The foam from the flotator enters the defoaming system 11, from where the resulting sediment is also sent to the repository 10. Since the electrocoagulator contains consumable electrodes in the stream, two devices are installed in parallel, which allows continuous filtrate processing when changing electrodes .

 The liquid 12, partially purified in the flotator electrocoagulator, is pumped by pump 12 to the clarification filter 13, the feature of which is the use of active, for example, limestone instead of an inert filter load, which allows combining the filtering process with pH adjustment - increasing it to a value of 6.5-7, which is necessary for effective subsequent biological treatment. Two filters are installed in parallel in the stream to ensure continuous operation of the stream when flushing one of the filters.

 The water preliminarily purified by the above methods, which has a significantly higher transparency compared to the initial one, enters the UV irradiation unit 5, in which flash xenon lamps are installed. The device is powered by a special unit. The intensity of UV irradiation is controlled by changing the number of pulses of the lamp glow per unit time. In this apparatus, the destruction of those organic compounds that were not planted during coagulation and, accordingly, removed during flotation occurs. These compounds have, as a rule, high stability, surface-active properties and are not absorbed by microorganisms during biological treatment.

 The treated filtrate is pumped to a bioremediation pump 15, where the remains of destroyed organic compounds, ammonia nitrogen and phosphates are removed from it. Bio-treatment is carried out in open-air aerobic and anaerobic plants 16. After bioprocessing, the purified filtrate enters the biopond 17, where it is refined, and the excess sludge formed during bioprocessing is assimilated.

 The purified effluent is partially supplied by pump 15 to the washing of the filters. Wash water returns to the beginning of the purification stream in the receiving tank 1.

 The proposed method for the treatment of heavily contaminated effluents is implemented using a device that is a production line consisting of the above devices installed in series and in parallel. With its help, not only sewage from landfills (filtrates) can be cleaned, but also the sewage most difficult to clean, such as, for example, from agricultural enterprises, livestock and poultry farms.

 The following examples illustrate the invention without limiting it.

 Example 1

 The initial waste water from the landfill has the composition shown in table 3.

 For purification, it is successively passed through the stages of ammonia stripping, pH adjustment, electrocoagulation, electroflotation, filtration with simultaneous adjustment of pH, UV treatment and biological treatment. At the same time, at the first stage of pH adjustment, its value is reduced to 5.2, and at the second stage it is increased to 7. For processing, a 200 kW xenon UV lamp is used, the number of pulses is 3 per second. The results of complex water purification by stages are given in table 4.

 As can be seen from the above data, the proposed technology provides the complete purification of heavily contaminated runoff from the landfill to the parameters that meet the requirements when discharged into fisheries.

 Example 2 (comparative).

 Source water of the same composition as in example 1 (table. 3) is treated according to the same scheme, but ammonia is not distilled off. In this case, the ammonia contained in the water negatively affects the electroflotation process and, therefore, the subsequent UV treatment and biological treatment. As a result (see Table 4), the treated wastewater does not meet the requirements for fishery water bodies in terms of BOD and COD.

 Example 3 (comparative).

 The filtrate having the composition shown in table. 3, are processed according to the following scheme: ammonia distillation, electrocoagulation and electroflotation, UV treatment and biological treatment. As can be seen from the table. 4, the absence of the stage of adjusting the pH to electrocoagulation and electroflotation leads to the ineffective conduct of these processes. In this case, only a slight clarification of the solution was observed, which, in turn, led to a deterioration in the conditions for UV treatment and a sharp decrease in its effectiveness. The data given in table. 4 show that the treated effluent does not meet specified standards.

 Example 4 (comparative).

 The filtrate having the same composition as in the previous examples is processed according to the scheme shown in FIG. 4, but carry out UV treatment using medium pressure mercury lamps. As shown in the table. 4, in this case, UV treatment is significantly less effective than when using a xenon lamp with a continuous emission spectrum. As a result, biological post-treatment of the runoff does not allow reaching the standards of fishery reservoirs.

Claims (3)

 1. The method of deep purification of highly concentrated wastewater by sequential physico-chemical treatment, consisting of adjusting the pH and filtering, and biological treatment, characterized in that the physicochemical treatment includes the following additional stages: distillation of ammonia, electrocoagulation, electroflotation, repeated adjustment of pH combined with filtering through a charge interacting with the solution and increasing its pH to 6 7, and ultraviolet treatment with a controlled irradiation intensity.  2. A device for the deep treatment of highly concentrated wastewater, which is a production line equipped with units for physico-chemical and biological treatment, characterized in that the unit for physico-chemical treatment includes series-connected devices for ammonia stripping and pH adjustment, an electrocoagulator, electroflotator, a filter with mineral loading, which provides, along with filtration, an increase in the pH of the solution, and an ultraviolet treatment unit.  3. The device according to claim 2, characterized in that the ultraviolet treatment unit consists of a xenon flash lamp having a continuous emission spectrum in the wavelength range of 200 to 2000 nm and a peak power in the ultraviolet range of 150 to 250 kW, the irradiation intensity of the ultraviolet lamp being automatically adjusted by setting the number of radiation pulses per unit time.

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